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Modelling the spatial correlation of earthquake ground motion: Insights from the literature, data from the 2016–2017 Central Italy earthquake sequence and ground-motion simulations
Journal Pre-proof Modelling the spatial correlation of earthquake ground motion: Insights from the literature, data from the 2016–2017 Central Italy earthquake sequence and ground-motion simulations
Erika Schiappapietra, John Douglas PII:
S0012-8252(19)30769-X
DOI:
https://doi.org/10.1016/j.earscirev.2020.103139
Reference:
EARTH 103139
To appear in:
Earth-Science Reviews
Received date:
19 November 2019
Revised date:
14 February 2020
Accepted date:
18 February 2020
Please cite this article as: E. Schiappapietra and J. Douglas, Modelling the spatial correlation of earthquake ground motion: Insights from the literature, data from the 2016–2017 Central Italy earthquake sequence and ground-motion simulations, EarthScience Reviews(2020), https://doi.org/10.1016/j.earscirev.2020.103139
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© 2020 Published by Elsevier.
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Modelling the Spatial Correlation of Earthquake Ground Motion: Insights from the literature, data from the 2016-2017 Central Italy earthquake sequence and ground-motion simulations Erika Schiappapietraa,1 , John Douglasa a
Department of Civil and Environmental Engineering, University of Strathclyde, Glasgow, G11XJ, UK.
ABSTRACT
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Over the past decades, researchers have given increasing attention to the modelling of the spatial
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correlation of earthquake ground motion intensity measures (IMs), particularly when the seismic
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risk of spatially distributed systems is being assessed. The quantification of the seismic performance of these systems requires the estimation of simultaneous IMs at multiple locations during the same
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earthquake, for which the correlation between pairs of locations needs to be defined. Numerous
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spatial correlation models of common IMs, such as peak ground acceleration and spectral acceleration, have been published. Although the functional forms of the models are generally
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similar, significant discrepancies exist in terms of the rate of decay of the correlation with
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increasing inter-site separation distance. The main reasons for such differences lie with the selected
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databases, the ground-motion models used to derive the spatial correlation models, estimation approaches and regional geological conditions. In this study, we aim to provide a comprehensive review of spatial correlation models, analysing factors that most affect the spatial dependency of IMs. We use strong-motion records from the 2016-2017 Central Italy earthquake sequence combined with ground-motion simulations to examine the influence of various factors on spatial correlation models. We investigate the dependency on: (1) the estimation method and model fitting technique; (2) the magnitude; (3) the response-spectral period; and (4) local-soil conditions. Our results suggest that the rate of decay is not only perioddependent, but also regionally-dependent, so that a single universal correlation model based on 1
Corresponding author. E-mail address: [email protected] (E. Schiappapietra)
1
Journal Pre-proof large datasets is not appropriate when describing the correlation behaviour of small geographical areas. Our outcomes could be used to guide the development of new spatial correlation models. Keywords: spatial correlation; ground-motion intensity measures; seismic hazard; strong ground motion; earthquake.
1. Introduction Stakeholders, such as government, search-and-rescue organizations and private companies, require
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a reliable evaluation of the ground-motion field to assess the effects of an earthquake for more informed risk management and decision making designed to reduce economic and human losses
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(e.g. Park et al., 2007; Weatherill et al., 2015). The probabilistic assessment of ground-motion
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intensity measures (IMs) at a single site is now a well-established technique, and sophisticated
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methods have been developed for this aim. Traditional seismic hazard and risk analysis tools usually determine the ground motion caused by an earthquake through ground motion prediction
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equations (GMPEs). GMPEs provide an estimate of the ground shaking and its associated aleatory
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variability at a given site, considering IMs at different sites as independent. The seismic risk
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assessment of spatially-distributed systems, such as long bridges, water and power lifelines and portfolios of buildings, however, require not only the estimation of simultaneous IMs at multiple locations during the same earthquake, but also the quantification of the correlation structure (e.g. Goda and Atkinson, 2009, 2010; Jayaram and Baker, 2009; Esposito and Iervolino, 2011, 2012; Weatherill et al., 2015; Wagener et al., 2016; Heresi and Miranda, 2019). Indeed, understanding the spatial characteristics of the ground motion arising from similarities in the seismic wave paths and local-site effects is needed to provide a more accurate representation of ground-motion fields (Verros et al., 2017). For instance, correlation models can be used to generate spatially-correlated random fields for use in developing either scenarios for future earthquakes or retro-scenarios of past events in terms of ground motion shaking, as well as for loss estimates. Iervolino (2013), among others, discuss the importance of considering regional hazard for calculation of aggregate risk. This 2
Journal Pre-proof author compared the annual rate of exceedance of a specific IM in at least one site among several with the corresponding site-specific hazard assessment, demonstrating that consideration of the joint probability of occurrence in the hazard computation leads to larger values than those obtained for individual sites. Similar conclusions are found in Sokolov and Ismail-Zadeh (2016) and Sokolov and Wenzel (2019). These studies outline the discrepancies between site-specific PSHA and multiple-site PSHA: smaller within-event correlations combined with larger reference areas make the hazard assessment for individual sites and multiple sites prone to remarkable differences.
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Besides, Sokolov and Wenzel (2019) demonstrated that the fraction of the reference area in which the design ground motion level will be exceeded depends not only on the considered return period,
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but also on the correlation model. For instance, for a return period of 475 years, there is a 10% of
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probability that the design ground motion level will be exceeded at least once in 50 years in 20%
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and 40% of the reference area when within-event residuals are uncorrelated and perfectly correlated, respectively, with corresponding impacts on loss estimates. The importance of defining
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spatially-correlated ground-motion fields in seismic risk assessment was also demonstrated by Park
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et al. (2007) and Sokolov and Wenzel (2011). Neglecting the spatial correlation may cause a bias in
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loss estimates, overestimating the most likely losses and underestimating rare losses. On the contrary, overestimating the correlation may lead to the opposite result. As remarked in Park et al. (2007), the effects of including or not the spatial correlation depend also on the considered portfolio. Analogous outcomes are provided in Crowley et al. (2008), in which the authors compared the variation of the mean damage ratio of the loss model, obtained considering uncorrelated and correlated ground motion fields as well as correlated ground motion fields constrained to the recordings available at a specified number of sites. Given observations at recording stations and including proper correlation models makes the variability of the ground motions lower, and hence the variability of the losses narrower.
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Journal Pre-proof Over the past decade, the number of studies on spatial correlation has increased significantly. Many models have been published (Table 1) and common findings suggest that: (1) within-event correlation decays rapidly with increasing inter-site separation distances, and (2) ground-motion IMs associated with longer response-spectral periods have larger correlation lengths (Goda and Hong, 2008; Jayaram and Baker, 2009; Esposito and Iervolino, 2012; Wagener et al., 2016; Sgobba et al., 2019). Nevertheless, a thorough comparison among the proposed models demonstrates significant inconsistencies, which may make the assessed seismic risk prone to large uncertainties
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(Figure 1). The majority of the studies are for different regions (e.g. California, Japan and Taiwan), suggesting that the underlying database as well as regional and local-site effects are likely to play
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first-order roles in the observed differences. Besides, the use of either existing GMPEs or ad hoc
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study-specific GMPEs as well as different estimation approaches may contribute to different
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outcomes. Further analyses are thus required to draw firm conclusions on the spatial correlation
Wang and Takada (2005)
Goda and Hong (2008)
Mw 6.7 1994 Northridge earthquake
6 earthquakes recorded in Japan and Taiwan (6.2 ≤ Mw ≤ 8.0)
6 Californian earthquakes (5.9 ≤ Mw ≤ 7.1)
Mw 7.6 Chi Chi Earthquake Goda and Atkinson (2009)
Considered GMPEs
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Boore et al. (2003)
Database
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References
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structures of different IMs.
K-NET and KiK-NET database: 106 earthquakes with Mw >= 5.5 and depth < 200 km
-
GMPE by Annaka et al. (1997) and by Midorikawa and Ohtake (2002) Ad hoc GMPE calibrated on 592 records from 39 Californian earthquake Boore and Atkinson (2007) Ad hoc GMPE
Spatial Correlation Model
Ground Motion Intensity Measure
Standard deviation of the difference of the logarithm of the PGA
Exponential
PGA
Direct estimation of the sample correlation coefficient
Exponential
PGV
Method
Semivariogram and direct estimation of the correlation coefficient
PGA and SA for T up to 3 s Exponential
Semivariogram and direct estimation of the correlation
Exponential
PGA and SA at T = 0.3; 1; 3 s PGA and SA (the final model is independent of T)
4
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Exponential
PGA and SA for T up to 3 s
Boore and Atkinson (2008) and Chiou and Youngs (2008)
Semivariogram (Classic estimator)
Exponential
SA for T up to 10 s
SK-NET, K-NET and KiKNET database: 20 earthquakes with 5.6 ≤ Mw ≤ 6.8 and 7 km ≤ depth ≤ 70 km
GMPE by Goda and Atkinson (2009)
Semivariogram
Exponential
PGA and SA (the final model is independent of T)
Jayaram and Baker (2010)
dataset used in Campbell and Bozorgnia (2008)
GMPE by Campbell and Bozorgnia (2008)
-
PGA and SA for T up to 10 s
Sokolov et al. (2010)
TSMIP network in Taiwan: 66 earthquakes with Ml ≥ 4.5 and depth ≤ 30 km
Ad hoc GMPE
Esposito and Iervolino (2011)
Subset of ESM (Mw 5-7.6 and Rjb 0-100km) and ITACA (Mw 4-6.9 and Rjb 0-196km)
Goda (2011)
PEER-NGA, K-NET, KiKNET and SK-net database: 41 earthquakes with Mw ≥ 5.5
Esposito and Iervolino (2012)
Subset of ESM (Mw 5-7.6 and Rjb 0-100km) and ITACA (Mw 4-6.9 and Rjb 0-196km)
Sokolov et al. (2012)
TSMIP network in Taiwan: 54 earthquakes with Ml ≥ 5.0 and depth ≤ 30 km
Du and Wang (2013)
5 Californian earthquakes (5.1 ≤ Mw ≤ 6.7) 3 Japanese earthquakes (6.6 ≤ Mw ≤ 6.8) Mw 7.6 Chi Chi Earthquake
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Correlation is computed within the GMPE regression Direct estimation of the sample correlation coefficient
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Mw 7.6 Chi Chi Earthquake
ESM: Akkar and Bommer (2010) ITACA: Bindi et al. (2010) GMPE by Boore and Atkinson (2008) and by Goda and Atkinson (2009) ESM: Akkar and Bommer (2010) ITACA: Bindi et al. (2011) GMPE by Sokolov et al. (2010) and by Tsai et al. (2006)
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Goda and Atkinson (2010)
6 Californian earthquakes (5.1 ≤ Mw ≤ 6.7)
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Jayaram and Baker (2009)
39 Californian earthquakes with Mw ≥ 5.0
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Hong et al. (2009)
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Ad hoc GMPE
Correlation is computed within the GMPE regression
GMPE by Campbell and Bozorgnia (2008, 2010, 2012)
Exponential
PGA
Semivariogram (Robust and classic estimator)
Exponential
PGA and PGV
Semivariogram
-
Semivariogram (Robust and classic estimator)
Exponential
SA: T up to 2 s for ITACA and 2.85 s for ESM
Semivariogram and direct estimation of the correlation coefficient
Exponential
PGA
Semivariogram (Robust estimator)
Exponential
SA for T up to 5 s, CAV and Ia
SA for T up to 2 s
5
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Bradley (2014)
2010-2011 Canterbury earthquakes
GMPE by Bradley (20102013)
Garakaninezhad and Bastami (2017)
9 earthquakes (5.2 ≤ Mw ≤ 7.6) occurred in California, Japan and Taiwan
Infantino et al. (2018)
Data from ground motion simulations carried out using the numerical code SPEED (Mw 6.0 Po Plain earthquake, Mw 6.5 Volvi earthquake, Mw 7.0 Istanbul scenario, Mw 6.5 Beijing scenario
Stafford et al. (2018)
24 earthquakes occurred in the Groningen field (2.5 ≤ Ml ≤ 3.6)
Chen and Baker (2019)
Physics-based simulations from the CyberShake platform (scenarios for souther California)
Heresi and Miranda (2019)
39 well recorded worldwide earthquakes
SA for T up to 6 s
-
Ia and CAV
Exponential
PGA and SA for T up to 1 s
-
PGA and SA for T up to 10 s
Semivariogram (Classic estimator)
Exponential
PGA and SA for T up to 3.5 s
Semivariogram (Classic estimator)
Exponential
SA for T up to 1 s
-
Semivariogram and direct estimation of the correlation coefficient
Exponential
PGA and SA for T up to 10 s
GMPE by Boore et al. (2014)
Semivariogram
Exponential
PGA and SA for T up to 10 s
Correlation is computed within the GMPE regression
Exponential
PGA and SA for T up to 4 s
Semivariogram
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8 earthquakes (3.5 ≤ Mw ≤ 5.1) recorded in the Marmara region
Semivariogram
-
Semivariogram
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Wagener et al. (2016)
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Subset of 203 Japanese earthquakes with more than 100 records
PGA and PGV
Ad hoc GMPE
Huang and Galasso (2019)
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Foulser-Piggott and Goda (2015)
ad hoc GMPE calibrated on 661 Japanese earthquakes with Mw ≥ 5.0, depth ≤ 150 km and R ≤ 300 km. GMPE by Akkar and Bommer (2010) GMPE by Campbell and Bozorgnia (2014)
Exponential
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84 Japanese earthquakes (4.2 ≤ Mw ≤ 7.4)
Semivariogram and direct estimation of the correlation coefficient Direct estimation of the sample correlation coefficient
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Sokolov and Wenzel (2013)
GMPE by Kanno et al. (2006) and by Goda and Atkinon (2009)
233 Italian earthquakes (4 ≤ Mw ≤ 6.9)
GMPE by Bommer et al. (2018)
Ad hoc GMPE
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Ming et al. (2019)
Simulations based on 62 Italian earthquakes (5 ≤ Mw ≤ 6.9) to validate the scoring algorithm approach
Ad hoc GMPE
Correlation is computed within the GMPE regression
Sgobba et al. (2019)
29 earthquakes of the 2012 Emilia sequence
GMPE by Lanzano et al. (2016)
Semivariogram (Classic estimator)
PGA
Exponential
PGA and SA for T up to 4 s
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Table 1: Main published correlation models. PGA is peak ground acceleration, PGV is peak ground velocity, SA is response spectral acceleration, Ia is Arias intensity, CAV is cumulative absolute velocity and T is spectral period. Mw is moment magnitude and RJB is Joyner-Boore distance. GMPEs is ground motion prediction equations.
Figure 1: A typical selection of spatial correlation models for PGA: B03: Boore et al. (2003); GH08: Goda and Hong (2008); GA09: Goda and Atkinson (2009); JB09: Jayaram and Baker (2009); GA10: Goda and Atkinson (2010); EI11 ESM: Esposito and Iervolino (2011) ESM database; EI11 ITACA : Esposito and Iervolino (2011) ITACA database; EI12 ITACA : Esposito and Iervolino (2012) ITACA database; S12: Sokolov et al. (2012); DW13: Du and Wang (2013); HM19: Heresi and Miranda (2019); HG19: Huang and Galasso (2019).
To address these issues, we use large databases of recorded strong ground motion from previous earthquakes and ground-motion simulations. In particular, we carry out a geostatistical analysis using the database of the 2016-2017 Central Italy earthquake sequence, which includes nearly 6900 records from 63 Mw ≥ 3.7 events (and nearly 1600 records from nine events with Mw ≥ 5.0) that occurred over a period of five months (August 2016 – January 2017). We choose this dataset 7
Journal Pre-proof because it allows: (1) removal of some of the uncertainties related to the underlying region; and (2) quantification of the variability of spatial correlation among different earthquakes when the same area is considered. Conversely, simulation of spatially-correlated ground-motion fields provides a controlled environment to test the factors that most influence the correlation structure. In this article our goal is to provide a well-structured review critically summarising the main findings to advance understanding of the spatial correlation of strong ground motion. We employ
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the outcomes from the simulations and observations to address the main issues and research gaps.
2. Basic Definitions
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The correlation of ground-motion IMs from an earthquake includes three main elements, namely:
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(1) the spatial correlation among residuals of the same IM for adjacent sites; (2) the correlation
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among residuals of different IMs at the same location; (3) the spatial cross-correlation among residuals of different IMs for closely spaced sites (Weatherill et al., 2015). We focus on the first of
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the above-mentioned elements.
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In general, the similarity of ground-motion IMs at two different sites depends on: (1) the earthquake
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source; (2) the propagation path from the source to the sites and local-site effects; (3) the position of closely-spaced sites in near-source conditions with respect to the main fault asperities (Park et al., 2007). The first of these aspects is commonly accounted for by the between-event residual provided by the GMPE. GMPEs relate a ground motion IM (e.g. peak ground acceleration, PGA; peak ground velocity, PGV; peak ground displacement, PGD; or pseudo-spectral acceleration for 5% of critical damping, SA) to a set of explanatory variables describing the source (e.g. magnitude and faulting mechanism), the wave propagation path (e.g. distance metric and regional effects) and the site conditions (e.g. soil classification) (e.g. Douglas and Edwards, 2016). IMs are commonly modelled
as
lognormally-distributed
random
variables,
through
a
mixed-effects
approach.
Therefore, GMPEs take the form: 8
Journal Pre-proof ̅ ( where
)
( )
is the IM of interest at the jth site due to the ith event, whereas ̅ is the predicted median
function of magnitude (M), distance from the source (R), local-site conditions (S) and other explanatory variables ( ).
is the between-event residual term, assumed as an independent,
identically and normally distributed random variable with zero mean and standard deviation
. It
denotes the systematic deviation of observed IMs associated to an event with respect to the GMPE represents the independent within-event
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prediction and does not depend on the site. Conversely,
residual term, which is site dependent as it accounts for differences from the average model due to
, and covariance function, which reflects the correlation of within-event
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by its mean function
follows a multivariate Gaussian distribution, completely defined
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the path and local-site effects.
(
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residuals: )
[
]
[
]
[
] ( )
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The within-event correlation between all pairs of sites during an earthquake due to the similarity of
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travel path and local-site effects depends on the inter-site separation distance. Typically, it is
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modelled as an exponential function:
( )
(
) ( )
where α and β are the model coefficients, usually inferred through a least-squares approach, and h is the separation distance. As above-mentioned, the between-event correlation, which arises from commonality of the rupture process, is taken into account by the
term and is defined as the ratio between the variability
components: ( )
9
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√
is the total variance and
is the standard deviation of the within-event
residuals. Therefore, the total correlation among residuals for closely spaced sites, which considers both the between-event and within-event variability, is given by:
( )
( )
( )
It is noted that the between-event correlation among different pairs is always positive, as a result of
( ) decays to zero with increasing separation distance (Heresi and Miranda,
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zero, although
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all sites sharing the same source rupture. As a matter of fact, the total correlation will never drop to
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2019). In this study, we focus only on the within-event correlation because the within-event residual
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spatial dependency of IMs (Stafford, 2012).
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term is the only component of the total variability that varies from site to site and thus affects the
Furthermore, only one observation from a given earthquake is available for each station, making it
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impossible to draw any inferences from it (Webster and Oliver, 2007). Therefore, the hypothesis of
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second-order stationarity and isotropy are generally assumed, so that the mean function of the random variable ( ) is constant for all sites, and the covariance
(
) , and thus the correlation,
orientation [ (
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depends only on the separation distance (h) between two sites and not on their absolute position and )
( )].
Finally, one should be aware that the correlation is usually computed on the residual terms rather than directly on the IM. Indeed, the diverse underlying distributions of each IM value, due to different explanatory variables (such as
), would make the assessment of the IMs correlation
inappropriate (Heresi and Miranda, 2019).
3. Databases
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Journal Pre-proof 3.1. Central Italy earthquake sequence Starting from 24th August 2016, one of the most important earthquake sequences ever recorded in Italy struck the Central Apennines between the municipalities of Amatrice and Norcia, causing widespread damage, thousands of homeless and invaluable losses for the historical heritage of the region. The first mainshock (Mw 6.0) struck on 24th August 2016 at 01:36 UTC near Amatrice and it was followed, within less than an hour, by a Mw 5.4 aftershock (Chiaraluce et al., 2017). After
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two months, two other large earthquakes occurred: a Mw 5.9 on 26th October 2016 at 19:18 UTC,
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near the village of Ussita and a Mw 6.5 on 30th October 2016 at 06:40 UTC with an epicentre close
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to Norcia (Luzi et al., 2017). Four other Mw ≥ 5.0 earthquakes occurred on 18th January 2017 near
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the villages of Campotosto and Montereale (Figure 2, Table 2). Event and stations metadata are from Lanzano et al. (2018). All the events, generated by normal fault segments, were recorded by
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permanent and temporary networks, set up to monitor the earthquake sequence at a high resolution
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al., 2017).
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and to retrieve more accurate observations of the ground shaking in the near-source region (Luzi et
In this study, we select data from strong-motion stations within an epicentral distance of 200 km.
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The distributions of the selected data with respect to distance, magnitude and distance, magnitude and number of stations per EC8 soil classes (Eurocode 8, 2004) are summarized in Figure 3. The site conditions at each strong-motion station are expressed through the EC8 soil categories, which is based either on the average shear-wave velocity of the upper-most 30 m (VS,30 ) or on the available geological information. Most of the selected stations are classified as site class B/stiff soil.
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Figure 2: Epicentres (stars) of the nine Mw ≥ 5.0 earthquakes of the sequence. Mw ≥ 2.5 aftershocks for one year after the Amatrice mainshock are also mapped with blue dots. [source: http://cnt.rm.ingv.it/]
Event
Event Time
Latitude [°]
Longitude [°]
Depth [km]
Amatrice
Mw
# Records
24/08/2016 01:36
42.70
13.23
8.1
6.0
158
Amatrice Aftershock
24/08/2016 02:33
42.79
13.15
8.0
5.3
138
Visso I
26/10/2016 17:10
42.88
13.13
8.7
5.4
158
Visso II
26/10/2016 19:18
42.91
13.13
7.5
5.9
166
Norcia
30/10/2016 06:40
42.83
13.11
9.2
6.5
159
Montereale I
18/01/2017 09:25
42.55
13.26
9.2
5.1
127
Montereale II
18/01/2017 10:14
42.53
13.28
9.1
5.5
141
Pizzoli I
18/01/2017 10:25
42.49
13.31
8.9
5.4
129
Pizzoli II
18/01/2017 10:33
42.48
13.28
10.0
5.0
124
Table 2: Main characteristics of the largest events of the Central Italy sequence [source: Lanzano et al. (2018)].
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Figure 3: (a) Records-distance distribution; (b) Magnitude-distance distribution; (c) Events-magnitude distribution; (d) Distribution of stations in terms of EC8 site classification. Distances are in terms of Joyner and Boore distance (Rjb, i.e. the distance to the surface projection of the rupture).
3.2. Simulated ground-motions fields To simulate spatially-correlated ground-motion fields, we employ the approach described in Strasser and Bommer (2009), which accounts for both the between- and within-event variabilities. The former is specified through the between-event standard deviation in the IMs computation, whereas the latter is included through the computation of a random field based on a multivariate normal distribution. The procedure includes the following steps:
13
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1. Generation of deterministic fields using GMPEs (
Lanzano et al. (2019) for shallow crustal earthquake in Italy, considering homogeneous rock site conditions (Figure 4a). 2. Generation of ground motion random fields (Figure 4c). (
The spatially correlated random field
) is computed through a multivariate
normal distribution characterized by an exponential correlation model with correlation and standard deviation
(5,
(0.1, 0.32 and 0.5) to allow a deeper insight into the impact of
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10 and 30 km) and
(see section 2). We choose different values of
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length
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these parameters on the analysis.
3. Generation of ground-motion stochastic fields (Figure 4b).
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This is obtained by combining steps 1 and 2:
The ground-motion fields are generated on a 200 km
(
)
( )
200 km grid with a 2 km resolution. Finally,
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we randomly locate strong-motion recording stations throughout the region and use the simulated pair to obtain stable results.
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IMs at these stations. We repeat the process 1000 times for each
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Figure 4: Example of deterministic (a), stochastic (b) and random (c) ground-motion fields. obtained through the above-described approach. PGAs are expressed in cm/s 2 . The triangles represent the stations used in the analysis.
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4. Modelling of spatial correlation
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4.1. Estimation of the within-event spatial correlation
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It is common practice to adopt an existing GMPE or an ad hoc study-specific GMPE to compute the within-event residuals at each site in order to assess the within-event spatial correlation
( ). This
can be estimated with two different approaches, namely: (1) computing directly the covariance and the correlation coefficient (e.g. Wang and Takada, 2005; Sokolov et al., 2010, 2012), or (2) calculating the sample semivariogram, which measures the average dissimilarity between spatially distributed data (e.g. Jayaram and Baker, 2009; Esposito and Iervolino, 2011, 2012; Wagener et al., 2016; Heresi and Miranda, 2019; Sgobba et al., 2019). In the first method, the spatial correlation is estimated as:
( )
(
)
( )
15
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and
are the within-event variabilities
for the ith and kth sites during the jth event with zero mean and standard deviation
.
The second method computes the experimental semivariogram to represent the spatial dependency of IMs values with varying separation distance, which is defined as: ̂( )
] ( )
[
in which Var indicates the variance. It is common practice to adopt two different estimators to
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compute the sample semivariogram: 1) Method of moments (Matheron, 1962)
∑{
pr
̂( )
}
( )
( )
e-
( )
Pr
where ̂ ( ) represents the empirical semivariogram and N(h) is the number of pairs separated by h.
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2) Estimator proposed by Cressie (1985)
∑ [ | ( )|
{
| ]
(
| ( )|
)
}
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̂( )
( )|
This is found to be a more robust estimator, being less sensitive to outliers (Esposito and Iervolino, 2012; Du and Wang, 2013; Oliver and Webster, 2014). Both the covariance and the semivariogram are calculated for each pair of stations ( inter-site spacing falls in a distance bin defined as
|
|
) whose
. Esposito and
Iervolino (2012) and Du and Wang (2013) suggest setting the bin size in such a way that there are at least 30 pairs in each bin. Other authors (e.g. Wagener et al., 2016) advise having at least 100 pairs per bin to have more reliable and representative estimations. Furthermore, the definition of primary importance.
is of
can be estimated either from the sample semivariogram at large separation
distances, where the within-event residuals are assumed to be uncorrelated, or as the standard 16
Journal Pre-proof deviation of the within-event residuals for a given event (Goda and Atkinson, 2010). Alternatively, Esposito and Iervolino (2012) employ the standard deviation related to the GMPE as
. However,
this approach is strongly discouraged by other studies, since using a constant value of
for
different events might lead to a biased within-event correlation (Heresi and Miranda, 2019, FoulserPiggott and Goda, 2015). Parametric functions are used to fit the experimental values computed either through the sample to be retrieved
f
semivariogram or covariance approaches. This allows for the spatial variation of
oo
for any separation distance h. Examples of basic second-order stationary and isotropic models are:
pr
(1) Matérn; (2) Exponential; and (3) Gaussian (Webster and Oliver, 2007). The exponential model
( )
(
)] (
)
Pr
[
e-
(Figure 5), which usually provides the best performance, takes the form:
al
where h is the separation distance, a and b are the sill and the range of the semivariogram and c is a given positive constant set to 3. The sill equals the variance of the data, whereas the range
( ) equals 0.95 times the sill. It is worth mentioning that in some studies (e.g.
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distance at which
rn
represents the distance beyond which the correlation between sites is negligible. The range is the
Wang and Takada, 2005; Huang and Galasso, 2019) c is set equal to 1. Consequently, the range outlines
the
distance
at
which
the
correlation equals
(
)
(
)
.
The
implementation of either one or the other value leads to a different meaning of the range, without however affecting the spatial correlation structure of the IM of interest. Moreover, under the hypothesis of second-order stationarity, the semivariogram and the covariance function are equivalent, so that the following relation holds (Oliver and Webster, 2014): ( ) being
( )
(
)
(
)
( )
(
)
. 17
Journal Pre-proof Consequently, combining Eq. (11) and Eq. (12), we have that: ( )
( )
) (
(
)
which is equivalent to Eq. (3). Furthermore, the hypothesis of second-order stationarity may sometimes not hold. The expected value of the random variable
may not be constant across all sites, but indeed varying
f
depending on the location. In such cases, the semivariogram ̂ ( ) increases with separation
oo
distance, without reaching a stable sill (Diggle and Ribeiro, 2007). These long-range spatial trends
pr
should be removed so that small-range correlation structures can be detected. It is common practice to model spatial trends through trend surface models, namely the mean function is described by
e-
either first- or second-order polynomial functions of the geographic coordinates (Diggle and
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Ribeiro, 2007; Oliver and Webster, 2014). Alternatively, the trend and the semivariogram of the residuals can be estimated all at once through the residual maximum likelihood approach, as
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rn
al
suggested by Oliver and Webster (2014).
Figure 5: Exponential model. The black solid line is the theoretical model, whereas black squares represent the experimental semivariogram. The sill and range parameters are also highlighted.
Different approaches have been used in previous studies to fit the experimental data, such as the weighted least-squares and manual-fitting techniques. Jayaram and Baker (2009), among others, suggest inferring the model parameters manually so that the experimental data are better fitted at 18
Journal Pre-proof shorter separation distances. This technique should, however, be discouraged as it involves a certain degree of subjectivity that can lead to prediction errors. Regarding the least-squares approach, weights can depend on either the separation distances (e.g. increasing the weights of data at shorter distances) or the number of pairs in each bin. 4.2. Modelling caveats The previously described approach suffers from some shortcomings. GMPEs (eq. 1) are usually
oo
f
developed through regression analysis using either the two-stage algorithm proposed by Joyner and Boore (1993) or the one-stage mixed-effects approach by Abrahamson and Youngs (1992),
pr
considering independent within-event residuals. The similarity of the earthquake source, path and
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local-site effects leads to spatially correlated within-event residuals. This issue was firstly
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investigated by Hong et al. (2009), who demonstrated that the inclusion of spatial correlation in GMPE development does not affect the estimated ground motion model coefficients but it does
al
affect the variability of the between- and within-event residuals. In particular, the between-event
rn
variance decreases, whereas the within-event component increases, with consequences for the assessment of seismic risk of spatially-distributed systems. Similarly, Jayaram and Baker (2010)
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adopted a different approach and drew analogous conclusions. While spatial correlation model parameters can be inferred from statistical analysis of residuals independently of GMPE regressions, caution must be applied in the estimation of Φ and τ. Ming et al. (2019) reviewed the studies by Hong et al. (2009) and Jayaram and Baker (2010), and pinpointed their main limitations. They proposed a new algorithm (the scoring estimation approach) that, while achieving the same results in terms of Φ and τ, provides more statistically robust ground-motion models along with spatial correlation parameters to improve seismic hazard and risk assessments. In addition, seismic risk analyses usually employ an average estimate of the correlation structure, derived considering heterogeneous databases, without accounting for its event-to-event variability. Goda (2011) investigated the event-to-event variability of within-event spatial correlation, studying 19
Journal Pre-proof 41 different earthquakes individually. He found that the model by Goda and Atkinson (2010) reasonably fits the overall median tendency. However,
units should be added to the same
spatial correlation model to take into account the event-to-event uncertainty. Likewise, Heresi and Miranda (2019) quantified the event-to-event variability, comparing the within-event residuals correlation of 39 well-recorded earthquakes. They provided general equations to calculate the median and dispersion of the correlation length (range), so that the uncertainty can be easily
f
accounted for in regional seismic risk computations.
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In Figure 6, we compare the outcomes obtained analysing the data from the 2016-2017 Central
pr
Italy sequence with the models proposed by Goda (2011) and Heresi and Miranda (2019) along with their event-to-event uncertainty. We follow the approach described in Heresi and Miranda
e-
(2019) to compute the central tendency and the standard deviation, based on the number of stations
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that recorded each event. The Central Italy database features a smaller event-to-event variability because all the earthquakes nucleated within the same region. Conversely, the two other models are
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calibrated on worldwide datasets, leading to a larger variability in terms of correlation length.
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According to our analysis, a region-specific variability should be considered when performing
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regional seismic hazard and risk assessment to obtain more accurate results.
20
Journal Pre-proof Figure 6: Correlation models proposed by Goda (2011) and Heresi and Miranda (2019) [HM19] and obtained considering data from the Central Italy sequence for PGA (a) and SA(3 s) (b). Solid lines represent the median values, whereas shadow areas indicate the event-to-event uncertainty. Black dashed line helps indicate the distances at which the correlation equals 0.05.
5. Major factors influencing spatial correlation In this section we present a detailed literature review and the results from our analyses, with the aim of understanding the main factors that affect the spatial correlation of ground-motion IMs.
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5.1. Dependence on the estimation approach
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In section 4.1 we described two different approaches to estimate the within-event spatial
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correlation, namely: (1) the covariance and correlation coefficient and (2) the semivariogram. The
e-
implementation of either one or the other technique should provide similar results as the semivariogram and the covariance are equivalent for second-order stationary random fields. Goda
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and Hong (2008) compared the results obtained for the Mw 7.6 Chi Chi earthquake using both the
al
approaches and found that the computation of the covariance provides slightly different estimates. Similarly, Goda and Atkinson (2009), while characterizing the spatial correlation of Japanese data,
rn
drew the same conclusions. The correlation decays faster when the correlation coefficient is directly
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computed, and some inconsistent trends may occur, especially if the number of available data is inadequate. Nevertheless, they provided a general correlation model by averaging the results obtained using both approaches, as subsequently suggested by Sokolov et al. (2012, 2013). In order to address this issue, we carry out a thorough geostatistical analysis of the within-event correlation structure using simulated spatially-correlated ground-motion fields. We compute the range implementing both the techniques and both the sample semivariogram estimators by varying the number of sites. As found by Goda and Hong (2008) and Goda and Atkinson (2009), the direct estimation of the correlation coefficient not only features slightly different results, but also a larger dispersion compared to the semivariogram approach in our simulations (Figure 7). Furthermore, the graph well illustrates how the availability of stations plays a crucial role in obtaining more robust 21
Journal Pre-proof outcomes: even though the mean of h0 assumes to some extent a constant value, the uncertainty
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f
halves as the number of stations increases.
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Figure 7: Estimated range h0 normalized by the true value of the range h* 0 as a function of the number of sites (stations) using: (a) the Cressie and Hawkins (robust) estimator; the Matheron (classic) estimator; and (c) the covariance approach. Grey squares represent the mean value, whereas the solid vertical lines indicate the variability of the estimates. The red dashed line signifies a ratio of 1.
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Most of the proposed models use the classic estimator of Mathéron (1962) to compute the sample
al
semivariogram. The estimates obtained are variances and as such they are sensitive to outliers, which might lead to less reliable semivariograms. A statistically more robust estimator was
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proposed by Cressie (1985) to down-weight the effects of atypical observations (Oliver and
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Webster, 2014). Esposito and Iervolino (2011, 2012) implemented both the estimators, concluding that there are negligible differences. Du and Wang (2013) suggested using the robust approach directly to obtain consistent estimations. Clearly, the two different estimators provide almost the same correlation distance in terms of average value, as observed in Figure 7 and according to Esposito and Iervolino (2011, 2012). However, a more in-depth analysis suggests that: (1) the classic estimator is likely to converge faster; (2) the two different approaches do not provide always the same range, as shown in Figure 8. In particular, the smaller the number of considered stations, the more significant are the differences. Although our simulations do not show which is the best semivariogram estimator, Oliver and Webster (2014) demonstrated that if the data features outliers, the classic estimator diverges from the input function, in contrast to the robust estimator. 22
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5.2. Dependence on the fitting method
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Figure 8: Comparison between the ranges obtained through both the classic and robust estimators, considering different numbers of stations.
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A number of methods have been proposed to fit experimental values by means of parametric
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models. The trial-and-error (manual fitting) and least-squares regression, among others, are the most common techniques. Jayaram and Baker (2009) recommend manually fitting the experimental semivariogram so that shorter separation distances, which are more important for engineering purposes, are weighted higher. Despite its high degree of subjectivity, this approach was chosen also by Du and Wang (2013) for its versatility in fitting the data. Esposito and Iervolino (2011) and Infantino et al. (2018) visually fitted experimental semivariograms, assuming the least-squares regression as a basis. Conversely, other studies, such as Esposito and Iervolino (2012), Sokolov et al. (2012), Wagener et al. (2016), Heresi and Miranda (2019) and Sgobba et al. (2019), adopt the weighted least-squares regression approach, using different weights. Some of the authors prioritise either the short separation distances or the number of pairs in each bin; others apply the same weight to all the experimental values, so that the model is fit equally over the full range of data. In 23
Journal Pre-proof our analysis, we opt for the weighted least squares regression, in which weights are computed based both on the number of pairs and on the separation distance, so that the impact of longer distances is minimized as they are associated with low correlations (Jayaram and Baker, 2009). However, we carry out a further analysis in which all the data are equally weighted to understand the influence of the fitting method on the correlation structure. Figure 9 illustrates how the different weightings lead to dissimilar results. A similar comparison can be found in Jayaram and Baker (2009), where the authors criticised the study by Wang and Takada (2005). Stafford et al. (2018) achieved similar
oo
f
outcomes, arguing that there is variability in the ranges due to the adopted technique. Therefore, according to Jayaram and Baker (2009), among others, we suggest prioritising models that fit the
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experimental data well at short separation distances, which have a significant impact on seismic risk
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rn
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estimates.
Figure 9: Correlation models obtained through the robust (a) and classic (b) estimators. Blue curves indicate the results in which the weights used to fit the experimental data are computed based on the number of pairs and separation distance; red curves represent the results in which equal weights are applied to all the data. Shadow area represent the standard deviation of the results computed on 1000 simulations. The standard deviation of the model with weights (8.7 and 7.12 km for the robust and classic estimators respectively) is smaller than the standard deviation of the model without weights (9.02 and 7.73 km).
5.3. Dependence on magnitude The relationship between magnitude and correlation length is one of the most debated topics in studies of spatial correlation. Some studies (e.g. Sokolov et al., 2012, 2013; Foulser-Piggott and 24
Journal Pre-proof Goda, 2015) argue that the range tends to increase with increasing magnitude because moderate-tolarge earthquakes feature lower frequency content and hence an additional non-random component. Conversely, other authors (e.g. Jayaram and Baker, 2009) did not find any correlation between these two parameters. Heresi and Miranda (2019) performed a statistical analysis and found that only a small ratio of the variability in terms of correlation length can be explained by considering the magnitude, in particular for SA at longer periods. Garakaninezhad and Bastami (2017) showed that there is a positive correlation between magnitude and anisotropy ratio (ratio between the ranges of
oo
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the direction with the largest and smallest spatial correlations, respectively) of residuals for the nine earthquakes analysed. This is valid only for PGA, however, and it does not apply to spectral
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accelerations.
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In Figure 10 we compare the ranges obtained for each
earthquake belonging to the
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Central Italy seismic sequence as a function of magnitude. The results do not suggest any clear relationship between range and magnitude, at least for this
interval, in agreement with the
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findings of Jayaram and Baker (2009). It is worth noting that both Sokolov et al. (2012, 2013) and
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Foulser-Piggott and Goda (2015) analysed a wider range of events in terms of magnitude, grouping . We believe that our analysed database
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as moderate-to-large earthquakes all events with
represents too narrow a magnitude interval to draw sound conclusions on the relationship between magnitude and range. Besides, it is biased towards small-magnitude earthquakes, which could influence the result. Other factors should be considered to explain the variability in terms of correlation length, especially when the same seismic region is considered. Stafford et al. (2018) demonstrated that the rupture process of events of equal magnitude has a significant contribution on the variability in the range. Likewise, while studying correlation spatial patterns using physicsbased ground-motion simulations, Chen and Baker (2019) found a dependence of the correlation on source effects and on the relative position of a site with respect to the fault asperities.
25
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Figure 10: Range as a function of magnitude: (a) PGA; (b) SA(4s). Ranges are obtained by means of the robust semivariogram. We also apply a detrending processing using second-order surface models to remove long-range spatial trends.
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5.4. Dependence on period
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Previous research (e.g. Goda and Hong, 2008; Jayaram and Baker, 2009; Esposito and Iervolino, 2012; Wagener et al., 2016; Infantino et al., 2018; Sgobba et al., 2019; Chen and Baker, 2019) has
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demonstrated that the spatial correlation structure is affected by the response-spectral period
rn
considered. Range and period are found to be directly proportional. This is consistent with studies
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on ground-motion coherency, a measure of similarity between waveforms and phases of two ground-motion time histories recorded at two different sites. Hough and Field (1996) demonstrated that ground motions at frequencies up to 2-3 Hz and distances up to 3-4 km are characterized by a high level of waveform coherence, which by contrast drops for shorter period ground motions. Zerva
and
Zervas (2002),
while investigating spatial coherency,
proved
that small-scale
heterogeneities in the travelling path strongly affect the short-period waves (short wavelengths), which therefore tend to be less coherent, in contrast to long-period waves. Figure 11 provides an overview of the correlation lengths as a function of period of the above-mentioned studies. All the range values in Figure 11 are computed as the distance at which the correlation equals 0.05 in order to compare the results. Esposito and Iervolino (2012) and Wagener et al. (2016) showed that at 26
Journal Pre-proof short periods (up to 0.5 s) it is not possible to clearly delineate a trend between range and period. Goda and Atkinson (2010) found that the correlation is clearly affected by the vibration period especially at short separation distances (h < 10 km), in contrast to greater distances (h > 50 km), where the models tend to converge towards similar results. Consequently, they proposed an average constant model (Figure 11), calibrated on the results obtained at nine different periods. To further test the hypothesis of a dependence of the correlation on period, here we present a model for the events.
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f
Central Italy sequence computed by pooling all the data from the nine
Figure 11: Range as a function of response-spectral period, T. The main studies are reported along with a model for the Central Italy seismic sequence, denoted as “This study”. This model is calibrated by pooling all the data from the nine Mw ≥ 5.0 events. The model of Jayaram and Baker (2009) refers to their model for heterogeneous soil condition, whereas the model of Du and Wang (2013) is computed considering a Vs30 correlation of 4.5 km.
As we summarise in Figure 12, we observe the increasing trend with period for all events of the sequence taken individually, as well.
27
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Figure 12: Range as a function of response-spectral period, T, computed using the robust estimator for the nine events of the sequence. In black we reported the weighted (geometric) average model, in which the weights are given based on the number of stations that recorded each event.
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5.5. Dependence on local site effects and geological structure Several studies (e.g. Jayaram and Baker, 2009; Sokolov et al., 2010, 2012; Du and Wang, 2013;
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Infantino et al., 2018; Chen and Baker, 2019) indicated that the level of correlation is strongly
rn
influenced by regional geologic and site conditions, especially when short-period IMs are of
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interest. Conversely, Heresi and Miranda (2019) demonstrated that the clustering of Vs30 values does not explain the high variability in the correlation length. To address this issue, we develop an ad hoc GMPE for the Central Italy sequence without accounting for different site conditions and then we introduce a site-specific correction factor to remove any dependency on local-site effects, following Sokolov et al. (2010, 2012, 2013). The within-event spatial correlation is understood as a non-random component in the residuals, which arises from neglecting a number of factors in the GMPE, such as site, path and azimuth as well as hanging-wall and footwall effects (Sokolov et al., 2012, 2013). Due to the shortage of data, we could not derive a correlation model for each site class, similarly to Sokolov et al. (2012, 2013). The following functional form is assumed: ̅
(
)
√
(
) 28
Journal Pre-proof where ̅ is the PGA or SA(T) for T equal to 0.2, 0.5, 1, 2, 3 and 4 s and
is the Joyner-Boore
distance (or the epicentral distance for those events where the fault geometry is not defined and the point-source approximation holds).
and
are the model coefficients inferred through
the maximum-likelihood regression method by Joyner and Boore (1993). It is noted that our main goal is to estimate the residuals for correlation purposes, and not to develop a new GMPE; therefore, we keep the functional form as simple as possible. The between-event and within-event residual components are evaluated using the mixed-effects approach. In the same way, we compute , which represents the site-specific deviations from the
oo
f
the site-specific correction term
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average model calibrated considering all sites in the dataset, as explained in Kotha et al. (2018). We evaluate the sample semivariogram through equation (eq. 10) and we fit the values using the
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weighted least-squares approach (section 5.2) considering an exponential model (eq. 11). We follow
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the approach of Esposito and Iervolino (2011, 2012) to pool data from different events. We repeat these steps including the site-specific correction term, so that the corrected IM is: ̅
(
)
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̅
Figure 13 provides an overview of the within-event correlation models obtained considering or not
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the site-specific correction term. Similarly to Sokolov et al. (2010, 2012, 2013), the range decreases if a correction factor is included in the analysis, suggesting that neglecting site conditions might add an artificial correlation due to systematic biases in the residuals (Stafford et al., 2018). Besides, the lower level of correlation found at longer periods (grey curve) requires further analysis, since the local-site effects influence is expected to decrease with increasing period, as demonstrated by Jayaram and Baker (2009) and Infantino et al. (2018), among others.
29
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Figure 13: (a) Range as a function of the response-spectral period, T, for within-event residuals (dWes) with and without the site correction factor; (b) Correlation function in terms of PGA for within-event residuals with and without the site correction factor. The black dashed line indicates a correlation of 0.05.
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Furthermore, the level of correlation of Vs30 values can be used as a proxy to represent either homogeneous or heterogeneous local-soil conditions in terms of local-site effects, since a smaller
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correlation indicates a more varied geological setting. Jayaram and Baker (2009) identified a
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positive relationship between clustering of Vs30 values and correlation of spectral accelerations, especially at shorter periods. They proposed a model to predict the range as a function of both the
rn
period and the Vs30 range. Similarly, Du and Wang (2013) drew analogous conclusions, illustrating
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that the influence of local-site effects on the correlation of spectral accelerations drops with increasing period. Sokolov et al. (2012) provided a relationship between the PGA range and the Vs30 correlation, after finding a dependency of these parameters for different regions in Taiwan. Garakaninezhad and Bastami (2017) found that the anisotropy ratio of residuals tends to increase as the anisotropy ratio of Vs30 increases. However, this positive correlation is significant only for PGA, similarly to the relationship with magnitude. To further emphasis this aspect, Figure 14 compares the above-mentioned studies along with a model calibrated on the
events of the Central
Italy sequence. We develop the latter using the code by Ming et al. (2019), which was also used in Huang and Galasso (2019) to study the correlation observed in Italian data. Two main observations are worthy of remark. Firstly, the effects of local-soil conditions on spatial correlation models are 30
Journal Pre-proof much greater at shorter periods, compared to longer periods where the different models practically overlap. Secondly, the comparison between the Huang and Galasso (2019) and Central Italy models suggests that the correlation strongly depends on the geological characteristics of the considered area, so that a single universal correlation model based on large datasets is not suitable to represent small regions. Indeed, the model of Huang and Galasso (2019) is obtained by including events that occurred in all of the Italian mainland, thus leading to an average spatial correlation model calibrated on diverse geological contexts, with variable spatial dependency of IMs. The same was
oo
f
also previously demonstrated by Sokolov et al. (2010, 2012, 2013) for Taiwan. Besides, this behaviour is particularly evident at shorter periods, in agreement with different studies, such as
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Jayaram and Baker (2009) and Du and Wang (2013), in which these authors demonstrated the
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impact of local-site effects as a function of period. Figure 11 illustrates this aspect: the Central Italy
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and the Huang and Galasso (2019) models nearly coincide for T>1 s.
Figure 14: Correlation function in terms of PGA (a) and SA at T = 2 s (b). The model referred as “This study” is computed by means of the code developed by Ming et al. (2019) using data from the nine central Italy earthquakes. The red shadow area represents the 95% confidence intervals of the central Italy model. The black dashed line indicates a correlation of 0.05.
5.6. Dependence on GMPEs To develop a correlation model either an existing GMPE or an ad hoc relation is used to assess the within-event residuals. Authors, such as Wang and Takada (2005), Jayaram and Baker (2009), 31
Journal Pre-proof Esposito and Iervolino (2011, 2012) and Wagener et al. (2016), employed and existing ground motion model in their analyses. Conversely, other authors such as Goda and Hong (2008), Goda and Atkinson (2009, 2010), Sokolov et al. (2010) and Infantino et al. (2018) developed a GMPE calibrated on their specific dataset. Du and Wang (2013) asserted that the chosen GMPE does not affect the correlation results. Analogously, Jayaram and Baker (2009) and Goda (2011) demonstrated that similar outcomes are achieved if different GMPEs are used. In contrast, Sokolov et al. (2010) maintained that the decomposition of the total aleatory variability into between- and
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within-event components is influenced by the particular GMPE and hence the spatial correlation is affected in turn, as it is calibrated on the residuals. Infantino et al. (2018) built a ground-motion
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model based on their databases to avoid any dependency on the GMPE. Likewise, we opt for the ad
e-
hoc GMPE approach and we develop a study-specific ground-motion model, as described in section event of the Central Italy sequence to
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5.5. We also calibrate ad hoc models for each
and
√
(
)
are the model coefficients inferred through a one-stage ordinary regression,
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where
√
rn
̅
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obtain a specific correlation model for each earthquake. We assume the following functional form:
which is justified as we are only using data from a single event each time. We show some of the results in Figure 10 and Figure 12.
To investigate the dependence of spatial correlation on the chosen ground-motion model, we repeat all the analyses using the GMPE provided by Bindi et al. (2011), which is also calibrated on Italian data. This model was found by Michelini et al. (2019) to be the most suitable to predict ground motions in shallow active crustal regions in Italy. Figure 15 presents a comparison between the correlation models obtained implementing both the ad hoc and Bindi et al. (2011) GMPEs. We plot the results illustrated in section 5.5, in which we consider both uncorrected and corrected withinevent residuals. Interestingly, the Bindi et al. (2011) model provides nearly the same range as the 32
Journal Pre-proof model obtained including a site correction term for short-period IMs. At longer periods, the Bindi et al. (2011) model approaches the range value inferred without incorporating any site correction factor. We interpret these outcomes by also considering the results that we present in section 5.5. The Bindi et al. (2011) GMPE takes into account the local-site effects through the definition of coefficients based on the EC8 soil categories. Local-soil conditions most influence the spatial correlation of short-period IMs and thus, it is not just chance that the correlation model inferred through the Bindi et al. (2011) GMPE tends to the range obtained implementing a site-specific
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correction term. Conversely, the influence of site conditions at longer periods is weaker, and the
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Bindi et al. (2011) and the uncorrected correlation models nearly coincide.
Figure 15: Within-event (dWes) correlation models for uncorrected and corrected residuals and computed considering the GMPE by Bindi et al. (2011): (a) PGA; (b) spectral acceleration for T equals 2 s.
Overall, we believe that any GMPE can be used, provided that the selected ground-motion model fits the data well, so that the residuals do not exhibit biases. Systematic deviations from the predicted median might be mapped as an additional artificial correlation, which inevitably would affect the seismic hazard and risk assessments of spatial distributed systems. This behaviour is shown in Figure 16, in which we compare the semivariograms obtained considering both the GMPE by Bindi et al. (2011) and Boore and Atkinson (2008). Clearly, the Boore and Atkinson (2008) semivariogram diverges from the Bindi et al. (2011) with increasing separation distance. 33
Journal Pre-proof This might be due to the trend of the within-event residuals with distance found for the Boore and Atkinson (2008) model, which reflects the inability of the GMPE to properly capture the observed
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IMs.
6. Conclusions
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Figure 16: Sample semivariogram obtained using the GMPEs by Boore and Atkinson (2008) and Bindi et al. (2011).
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In this article, we aimed to provide insights into the spatial correlations of earthquake ground-
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motion intensity measures. A number of studies, such as Park et al. (2007) Goda and Atkinson (2009) Esposito and Iervolino (2011) and Verros et al. (2017), highlighted the importance of considering such spatial correlations in seismic hazard and risk analysis, especially when the seismic risk of spatially distributed systems has to be evaluated. Nevertheless, the correlation models proposed over the past two decades feature significant discrepancies, which may lead to underestimation or overestimation of the assessed seismic risk. Therefore, in this article, we critically summarised the main findings of previous studies and we attempt to address the primary questions about ground-motion spatial correlation. We showed the two main approaches to estimate the spatial correlation of ground-motion intensity measures. In principle, the implementation of either one or the other technique is expected to 34
Journal Pre-proof provide similar results, as the semivariogram and the covariance are equivalent for second-order stationary random fields. Nevertheless, in agreement with Goda and Hong (2008) and Goda and Atkinson (2009), we find that the results slightly diverge. Concerning the computation of the semivariogram, the robust estimator (Cressie) is understood to be less sensitive to atypical observations, as demonstrated by Oliver and Webster (2014). Therefore, we preferred using this estimator in contrast to the classic one throughout the analyses, although the results from our simulations did not find any significant difference between the two estimators. To fit experimental
oo
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data, we advise prioritising those techniques that weigh the shorter separation distances more highly, since these distances have a strong impact on seismic hazard and risk assessments of
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spatially-distributed systems. At the same time, we discourage adopting a manual fitting due to the
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high level of subjectivity involved.
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Similarly to Jayaram and Baker (2009), we do not find any relationship between magnitude and correlation distance. We are aware that the analysed dataset is limited in terms of magnitude range
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(Mw 4.0 to 6.5), so that firm conclusions cannot be drawn on this aspect. However, we believe that
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magnitude itself cannot explain the large variability of correlation distance values, especially when
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the same region is considered. Thus, other source effects, such as directivity, azimuth and hanging wall and footwall effects, should be accounted for, as outlined in Stafford et al. (2018) and Chen and Baker (2019).
We found a positive correlation between the range and response-spectral period, as expected from the literature. Small-scale heterogeneities in the travel path tend to affect less the long-period waves, which turn out to be more correlated, compared to high- frequency waves. We analysed the dependency of the spatial correlation on local-soil conditions, illustrating that the influence of local-site effects and regional geology is period-dependent, as demonstrated by several authors, such as Jayaram and Baker (2009), Du and Wang (2013) and Infantino et al. (2018). The comparison between our analysis of data from Central Italy and the work proposed by Huang and 35
Journal Pre-proof Galasso (2019) is significant. Firstly, it confirms the hypothesis that the dependency of spatial correlation on site conditions in terms of local-site effects decreases as the period increases. Secondly, it suggests that a single rate of decay of the correlation as a function of the inter-site separation distance is not suitable for seismic hazard and risk assessment, as the range appears to be regionally-dependent, even though all the data came from the same country (Italy in this case). We believe that region-specific spatial correlation models should be derived.
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Finally, our results suggest that any suitable ground-motion model can be applied in correlation
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studies, provided that the residuals do not exhibit significant trends or biases, which might result in
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an apparent larger correlation. Therefore, a single correlation model could be used in seismic hazard analysis even if many different GMPEs are employed to estimate ground-motion parameters.
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However, as suggested by Sokolov et al. (2012), implementing a logic tree for correlation models as
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already incorporated in probabilistic seismic hazard assessments, should be encouraged to account
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for the high uncertainty in spatial correlation models.
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We note that generally the models are poorly constrained at short separation distances (less than 2 km), due to a shortage of observations (Goda and Atkinson, 2010; Wagener et al., 2016). Results of
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ground motion simulations could provide better constraints to further advance insights into the spatial correlation of ground motions.
Data and resources
The full dataset of strong-motion waveforms of the nine
earthquakes of the 2016-2017
Central Italy sequences is available at the Engineering Strong Motion database (ESM, http://esm.mi.ingv.it, last accessed September 2019) and the Italian ACcelerometric Archive (ITACA, http://itaca.mi.ingv.it, last accessed September 2019). The full dataset of recordings of the events of the 2016-2017 Central Italy sequences is available at http://cnt.rm.ingv.it/ (last accessed September 2019).
36
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Acknowledgements
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We thank the research group of Dr Francesca Pacor at INGV (Istituto di Geofisica e Vulcanologia) for providing the dataset related to the events that occurred during the Central Italy earthquake sequence. We also thank Dr Sreeram Reddy Kotha for his helpful suggestions about implementing mixed-effects regressions in R. We thank Dr Deyu Ming for help with the MATLAB program to implement the approach of Ming et al. (2019). We wish to thank Professor Jack Baker’s research group at Stanford University for providing valuable feedback on our analyses. We are grateful to Impact Forecasting for fruitful discussions on hazard footprints. We thank Graeme Weatherill and an anonymous reviewer for their constructive advice on improving the manuscript. Finally, we thank the University of Strathclyde for funding the PhD during which the work was undertaken.
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Erika Schiappapietra, John Douglas PII:
S0012-8252(19)30769-X
DOI:
https://doi.org/10.1016/j.earscirev.2020.103139
Reference:
EARTH 103139
To appear in:
Earth-Science Reviews
Received date:
19 November 2019
Revised date:
14 February 2020
Accepted date:
18 February 2020
Please cite this article as: E. Schiappapietra and J. Douglas, Modelling the spatial correlation of earthquake ground motion: Insights from the literature, data from the 2016–2017 Central Italy earthquake sequence and ground-motion simulations, EarthScience Reviews(2020), https://doi.org/10.1016/j.earscirev.2020.103139
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Modelling the Spatial Correlation of Earthquake Ground Motion: Insights from the literature, data from the 2016-2017 Central Italy earthquake sequence and ground-motion simulations Erika Schiappapietraa,1 , John Douglasa a
Department of Civil and Environmental Engineering, University of Strathclyde, Glasgow, G11XJ, UK.
ABSTRACT
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Over the past decades, researchers have given increasing attention to the modelling of the spatial
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correlation of earthquake ground motion intensity measures (IMs), particularly when the seismic
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risk of spatially distributed systems is being assessed. The quantification of the seismic performance of these systems requires the estimation of simultaneous IMs at multiple locations during the same
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earthquake, for which the correlation between pairs of locations needs to be defined. Numerous
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spatial correlation models of common IMs, such as peak ground acceleration and spectral acceleration, have been published. Although the functional forms of the models are generally
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similar, significant discrepancies exist in terms of the rate of decay of the correlation with
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increasing inter-site separation distance. The main reasons for such differences lie with the selected
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databases, the ground-motion models used to derive the spatial correlation models, estimation approaches and regional geological conditions. In this study, we aim to provide a comprehensive review of spatial correlation models, analysing factors that most affect the spatial dependency of IMs. We use strong-motion records from the 2016-2017 Central Italy earthquake sequence combined with ground-motion simulations to examine the influence of various factors on spatial correlation models. We investigate the dependency on: (1) the estimation method and model fitting technique; (2) the magnitude; (3) the response-spectral period; and (4) local-soil conditions. Our results suggest that the rate of decay is not only perioddependent, but also regionally-dependent, so that a single universal correlation model based on 1
Corresponding author. E-mail address: [email protected] (E. Schiappapietra)
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Journal Pre-proof large datasets is not appropriate when describing the correlation behaviour of small geographical areas. Our outcomes could be used to guide the development of new spatial correlation models. Keywords: spatial correlation; ground-motion intensity measures; seismic hazard; strong ground motion; earthquake.
1. Introduction Stakeholders, such as government, search-and-rescue organizations and private companies, require
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a reliable evaluation of the ground-motion field to assess the effects of an earthquake for more informed risk management and decision making designed to reduce economic and human losses
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(e.g. Park et al., 2007; Weatherill et al., 2015). The probabilistic assessment of ground-motion
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intensity measures (IMs) at a single site is now a well-established technique, and sophisticated
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methods have been developed for this aim. Traditional seismic hazard and risk analysis tools usually determine the ground motion caused by an earthquake through ground motion prediction
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equations (GMPEs). GMPEs provide an estimate of the ground shaking and its associated aleatory
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variability at a given site, considering IMs at different sites as independent. The seismic risk
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assessment of spatially-distributed systems, such as long bridges, water and power lifelines and portfolios of buildings, however, require not only the estimation of simultaneous IMs at multiple locations during the same earthquake, but also the quantification of the correlation structure (e.g. Goda and Atkinson, 2009, 2010; Jayaram and Baker, 2009; Esposito and Iervolino, 2011, 2012; Weatherill et al., 2015; Wagener et al., 2016; Heresi and Miranda, 2019). Indeed, understanding the spatial characteristics of the ground motion arising from similarities in the seismic wave paths and local-site effects is needed to provide a more accurate representation of ground-motion fields (Verros et al., 2017). For instance, correlation models can be used to generate spatially-correlated random fields for use in developing either scenarios for future earthquakes or retro-scenarios of past events in terms of ground motion shaking, as well as for loss estimates. Iervolino (2013), among others, discuss the importance of considering regional hazard for calculation of aggregate risk. This 2
Journal Pre-proof author compared the annual rate of exceedance of a specific IM in at least one site among several with the corresponding site-specific hazard assessment, demonstrating that consideration of the joint probability of occurrence in the hazard computation leads to larger values than those obtained for individual sites. Similar conclusions are found in Sokolov and Ismail-Zadeh (2016) and Sokolov and Wenzel (2019). These studies outline the discrepancies between site-specific PSHA and multiple-site PSHA: smaller within-event correlations combined with larger reference areas make the hazard assessment for individual sites and multiple sites prone to remarkable differences.
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Besides, Sokolov and Wenzel (2019) demonstrated that the fraction of the reference area in which the design ground motion level will be exceeded depends not only on the considered return period,
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but also on the correlation model. For instance, for a return period of 475 years, there is a 10% of
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probability that the design ground motion level will be exceeded at least once in 50 years in 20%
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and 40% of the reference area when within-event residuals are uncorrelated and perfectly correlated, respectively, with corresponding impacts on loss estimates. The importance of defining
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spatially-correlated ground-motion fields in seismic risk assessment was also demonstrated by Park
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et al. (2007) and Sokolov and Wenzel (2011). Neglecting the spatial correlation may cause a bias in
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loss estimates, overestimating the most likely losses and underestimating rare losses. On the contrary, overestimating the correlation may lead to the opposite result. As remarked in Park et al. (2007), the effects of including or not the spatial correlation depend also on the considered portfolio. Analogous outcomes are provided in Crowley et al. (2008), in which the authors compared the variation of the mean damage ratio of the loss model, obtained considering uncorrelated and correlated ground motion fields as well as correlated ground motion fields constrained to the recordings available at a specified number of sites. Given observations at recording stations and including proper correlation models makes the variability of the ground motions lower, and hence the variability of the losses narrower.
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Journal Pre-proof Over the past decade, the number of studies on spatial correlation has increased significantly. Many models have been published (Table 1) and common findings suggest that: (1) within-event correlation decays rapidly with increasing inter-site separation distances, and (2) ground-motion IMs associated with longer response-spectral periods have larger correlation lengths (Goda and Hong, 2008; Jayaram and Baker, 2009; Esposito and Iervolino, 2012; Wagener et al., 2016; Sgobba et al., 2019). Nevertheless, a thorough comparison among the proposed models demonstrates significant inconsistencies, which may make the assessed seismic risk prone to large uncertainties
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(Figure 1). The majority of the studies are for different regions (e.g. California, Japan and Taiwan), suggesting that the underlying database as well as regional and local-site effects are likely to play
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first-order roles in the observed differences. Besides, the use of either existing GMPEs or ad hoc
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study-specific GMPEs as well as different estimation approaches may contribute to different
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outcomes. Further analyses are thus required to draw firm conclusions on the spatial correlation
Wang and Takada (2005)
Goda and Hong (2008)
Mw 6.7 1994 Northridge earthquake
6 earthquakes recorded in Japan and Taiwan (6.2 ≤ Mw ≤ 8.0)
6 Californian earthquakes (5.9 ≤ Mw ≤ 7.1)
Mw 7.6 Chi Chi Earthquake Goda and Atkinson (2009)
Considered GMPEs
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Boore et al. (2003)
Database
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References
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structures of different IMs.
K-NET and KiK-NET database: 106 earthquakes with Mw >= 5.5 and depth < 200 km
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GMPE by Annaka et al. (1997) and by Midorikawa and Ohtake (2002) Ad hoc GMPE calibrated on 592 records from 39 Californian earthquake Boore and Atkinson (2007) Ad hoc GMPE
Spatial Correlation Model
Ground Motion Intensity Measure
Standard deviation of the difference of the logarithm of the PGA
Exponential
PGA
Direct estimation of the sample correlation coefficient
Exponential
PGV
Method
Semivariogram and direct estimation of the correlation coefficient
PGA and SA for T up to 3 s Exponential
Semivariogram and direct estimation of the correlation
Exponential
PGA and SA at T = 0.3; 1; 3 s PGA and SA (the final model is independent of T)
4
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Exponential
PGA and SA for T up to 3 s
Boore and Atkinson (2008) and Chiou and Youngs (2008)
Semivariogram (Classic estimator)
Exponential
SA for T up to 10 s
SK-NET, K-NET and KiKNET database: 20 earthquakes with 5.6 ≤ Mw ≤ 6.8 and 7 km ≤ depth ≤ 70 km
GMPE by Goda and Atkinson (2009)
Semivariogram
Exponential
PGA and SA (the final model is independent of T)
Jayaram and Baker (2010)
dataset used in Campbell and Bozorgnia (2008)
GMPE by Campbell and Bozorgnia (2008)
-
PGA and SA for T up to 10 s
Sokolov et al. (2010)
TSMIP network in Taiwan: 66 earthquakes with Ml ≥ 4.5 and depth ≤ 30 km
Ad hoc GMPE
Esposito and Iervolino (2011)
Subset of ESM (Mw 5-7.6 and Rjb 0-100km) and ITACA (Mw 4-6.9 and Rjb 0-196km)
Goda (2011)
PEER-NGA, K-NET, KiKNET and SK-net database: 41 earthquakes with Mw ≥ 5.5
Esposito and Iervolino (2012)
Subset of ESM (Mw 5-7.6 and Rjb 0-100km) and ITACA (Mw 4-6.9 and Rjb 0-196km)
Sokolov et al. (2012)
TSMIP network in Taiwan: 54 earthquakes with Ml ≥ 5.0 and depth ≤ 30 km
Du and Wang (2013)
5 Californian earthquakes (5.1 ≤ Mw ≤ 6.7) 3 Japanese earthquakes (6.6 ≤ Mw ≤ 6.8) Mw 7.6 Chi Chi Earthquake
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Correlation is computed within the GMPE regression Direct estimation of the sample correlation coefficient
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Mw 7.6 Chi Chi Earthquake
ESM: Akkar and Bommer (2010) ITACA: Bindi et al. (2010) GMPE by Boore and Atkinson (2008) and by Goda and Atkinson (2009) ESM: Akkar and Bommer (2010) ITACA: Bindi et al. (2011) GMPE by Sokolov et al. (2010) and by Tsai et al. (2006)
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Goda and Atkinson (2010)
6 Californian earthquakes (5.1 ≤ Mw ≤ 6.7)
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Jayaram and Baker (2009)
39 Californian earthquakes with Mw ≥ 5.0
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Hong et al. (2009)
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Ad hoc GMPE
Correlation is computed within the GMPE regression
GMPE by Campbell and Bozorgnia (2008, 2010, 2012)
Exponential
PGA
Semivariogram (Robust and classic estimator)
Exponential
PGA and PGV
Semivariogram
-
Semivariogram (Robust and classic estimator)
Exponential
SA: T up to 2 s for ITACA and 2.85 s for ESM
Semivariogram and direct estimation of the correlation coefficient
Exponential
PGA
Semivariogram (Robust estimator)
Exponential
SA for T up to 5 s, CAV and Ia
SA for T up to 2 s
5
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Bradley (2014)
2010-2011 Canterbury earthquakes
GMPE by Bradley (20102013)
Garakaninezhad and Bastami (2017)
9 earthquakes (5.2 ≤ Mw ≤ 7.6) occurred in California, Japan and Taiwan
Infantino et al. (2018)
Data from ground motion simulations carried out using the numerical code SPEED (Mw 6.0 Po Plain earthquake, Mw 6.5 Volvi earthquake, Mw 7.0 Istanbul scenario, Mw 6.5 Beijing scenario
Stafford et al. (2018)
24 earthquakes occurred in the Groningen field (2.5 ≤ Ml ≤ 3.6)
Chen and Baker (2019)
Physics-based simulations from the CyberShake platform (scenarios for souther California)
Heresi and Miranda (2019)
39 well recorded worldwide earthquakes
SA for T up to 6 s
-
Ia and CAV
Exponential
PGA and SA for T up to 1 s
-
PGA and SA for T up to 10 s
Semivariogram (Classic estimator)
Exponential
PGA and SA for T up to 3.5 s
Semivariogram (Classic estimator)
Exponential
SA for T up to 1 s
-
Semivariogram and direct estimation of the correlation coefficient
Exponential
PGA and SA for T up to 10 s
GMPE by Boore et al. (2014)
Semivariogram
Exponential
PGA and SA for T up to 10 s
Correlation is computed within the GMPE regression
Exponential
PGA and SA for T up to 4 s
Semivariogram
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8 earthquakes (3.5 ≤ Mw ≤ 5.1) recorded in the Marmara region
Semivariogram
-
Semivariogram
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Wagener et al. (2016)
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Subset of 203 Japanese earthquakes with more than 100 records
PGA and PGV
Ad hoc GMPE
Huang and Galasso (2019)
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Foulser-Piggott and Goda (2015)
ad hoc GMPE calibrated on 661 Japanese earthquakes with Mw ≥ 5.0, depth ≤ 150 km and R ≤ 300 km. GMPE by Akkar and Bommer (2010) GMPE by Campbell and Bozorgnia (2014)
Exponential
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84 Japanese earthquakes (4.2 ≤ Mw ≤ 7.4)
Semivariogram and direct estimation of the correlation coefficient Direct estimation of the sample correlation coefficient
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Sokolov and Wenzel (2013)
GMPE by Kanno et al. (2006) and by Goda and Atkinon (2009)
233 Italian earthquakes (4 ≤ Mw ≤ 6.9)
GMPE by Bommer et al. (2018)
Ad hoc GMPE
6
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Ming et al. (2019)
Simulations based on 62 Italian earthquakes (5 ≤ Mw ≤ 6.9) to validate the scoring algorithm approach
Ad hoc GMPE
Correlation is computed within the GMPE regression
Sgobba et al. (2019)
29 earthquakes of the 2012 Emilia sequence
GMPE by Lanzano et al. (2016)
Semivariogram (Classic estimator)
PGA
Exponential
PGA and SA for T up to 4 s
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Table 1: Main published correlation models. PGA is peak ground acceleration, PGV is peak ground velocity, SA is response spectral acceleration, Ia is Arias intensity, CAV is cumulative absolute velocity and T is spectral period. Mw is moment magnitude and RJB is Joyner-Boore distance. GMPEs is ground motion prediction equations.
Figure 1: A typical selection of spatial correlation models for PGA: B03: Boore et al. (2003); GH08: Goda and Hong (2008); GA09: Goda and Atkinson (2009); JB09: Jayaram and Baker (2009); GA10: Goda and Atkinson (2010); EI11 ESM: Esposito and Iervolino (2011) ESM database; EI11 ITACA : Esposito and Iervolino (2011) ITACA database; EI12 ITACA : Esposito and Iervolino (2012) ITACA database; S12: Sokolov et al. (2012); DW13: Du and Wang (2013); HM19: Heresi and Miranda (2019); HG19: Huang and Galasso (2019).
To address these issues, we use large databases of recorded strong ground motion from previous earthquakes and ground-motion simulations. In particular, we carry out a geostatistical analysis using the database of the 2016-2017 Central Italy earthquake sequence, which includes nearly 6900 records from 63 Mw ≥ 3.7 events (and nearly 1600 records from nine events with Mw ≥ 5.0) that occurred over a period of five months (August 2016 – January 2017). We choose this dataset 7
Journal Pre-proof because it allows: (1) removal of some of the uncertainties related to the underlying region; and (2) quantification of the variability of spatial correlation among different earthquakes when the same area is considered. Conversely, simulation of spatially-correlated ground-motion fields provides a controlled environment to test the factors that most influence the correlation structure. In this article our goal is to provide a well-structured review critically summarising the main findings to advance understanding of the spatial correlation of strong ground motion. We employ
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the outcomes from the simulations and observations to address the main issues and research gaps.
2. Basic Definitions
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The correlation of ground-motion IMs from an earthquake includes three main elements, namely:
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(1) the spatial correlation among residuals of the same IM for adjacent sites; (2) the correlation
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among residuals of different IMs at the same location; (3) the spatial cross-correlation among residuals of different IMs for closely spaced sites (Weatherill et al., 2015). We focus on the first of
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the above-mentioned elements.
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In general, the similarity of ground-motion IMs at two different sites depends on: (1) the earthquake
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source; (2) the propagation path from the source to the sites and local-site effects; (3) the position of closely-spaced sites in near-source conditions with respect to the main fault asperities (Park et al., 2007). The first of these aspects is commonly accounted for by the between-event residual provided by the GMPE. GMPEs relate a ground motion IM (e.g. peak ground acceleration, PGA; peak ground velocity, PGV; peak ground displacement, PGD; or pseudo-spectral acceleration for 5% of critical damping, SA) to a set of explanatory variables describing the source (e.g. magnitude and faulting mechanism), the wave propagation path (e.g. distance metric and regional effects) and the site conditions (e.g. soil classification) (e.g. Douglas and Edwards, 2016). IMs are commonly modelled
as
lognormally-distributed
random
variables,
through
a
mixed-effects
approach.
Therefore, GMPEs take the form: 8
Journal Pre-proof ̅ ( where
)
( )
is the IM of interest at the jth site due to the ith event, whereas ̅ is the predicted median
function of magnitude (M), distance from the source (R), local-site conditions (S) and other explanatory variables ( ).
is the between-event residual term, assumed as an independent,
identically and normally distributed random variable with zero mean and standard deviation
. It
denotes the systematic deviation of observed IMs associated to an event with respect to the GMPE represents the independent within-event
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prediction and does not depend on the site. Conversely,
residual term, which is site dependent as it accounts for differences from the average model due to
, and covariance function, which reflects the correlation of within-event
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by its mean function
follows a multivariate Gaussian distribution, completely defined
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the path and local-site effects.
(
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residuals: )
[
]
[
]
[
] ( )
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The within-event correlation between all pairs of sites during an earthquake due to the similarity of
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travel path and local-site effects depends on the inter-site separation distance. Typically, it is
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modelled as an exponential function:
( )
(
) ( )
where α and β are the model coefficients, usually inferred through a least-squares approach, and h is the separation distance. As above-mentioned, the between-event correlation, which arises from commonality of the rupture process, is taken into account by the
term and is defined as the ratio between the variability
components: ( )
9
Journal Pre-proof in which
√
is the total variance and
is the standard deviation of the within-event
residuals. Therefore, the total correlation among residuals for closely spaced sites, which considers both the between-event and within-event variability, is given by:
( )
( )
( )
It is noted that the between-event correlation among different pairs is always positive, as a result of
( ) decays to zero with increasing separation distance (Heresi and Miranda,
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zero, although
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all sites sharing the same source rupture. As a matter of fact, the total correlation will never drop to
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2019). In this study, we focus only on the within-event correlation because the within-event residual
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spatial dependency of IMs (Stafford, 2012).
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term is the only component of the total variability that varies from site to site and thus affects the
Furthermore, only one observation from a given earthquake is available for each station, making it
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impossible to draw any inferences from it (Webster and Oliver, 2007). Therefore, the hypothesis of
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second-order stationarity and isotropy are generally assumed, so that the mean function of the random variable ( ) is constant for all sites, and the covariance
(
) , and thus the correlation,
orientation [ (
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depends only on the separation distance (h) between two sites and not on their absolute position and )
( )].
Finally, one should be aware that the correlation is usually computed on the residual terms rather than directly on the IM. Indeed, the diverse underlying distributions of each IM value, due to different explanatory variables (such as
), would make the assessment of the IMs correlation
inappropriate (Heresi and Miranda, 2019).
3. Databases
10
Journal Pre-proof 3.1. Central Italy earthquake sequence Starting from 24th August 2016, one of the most important earthquake sequences ever recorded in Italy struck the Central Apennines between the municipalities of Amatrice and Norcia, causing widespread damage, thousands of homeless and invaluable losses for the historical heritage of the region. The first mainshock (Mw 6.0) struck on 24th August 2016 at 01:36 UTC near Amatrice and it was followed, within less than an hour, by a Mw 5.4 aftershock (Chiaraluce et al., 2017). After
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two months, two other large earthquakes occurred: a Mw 5.9 on 26th October 2016 at 19:18 UTC,
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near the village of Ussita and a Mw 6.5 on 30th October 2016 at 06:40 UTC with an epicentre close
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to Norcia (Luzi et al., 2017). Four other Mw ≥ 5.0 earthquakes occurred on 18th January 2017 near
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the villages of Campotosto and Montereale (Figure 2, Table 2). Event and stations metadata are from Lanzano et al. (2018). All the events, generated by normal fault segments, were recorded by
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permanent and temporary networks, set up to monitor the earthquake sequence at a high resolution
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al., 2017).
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and to retrieve more accurate observations of the ground shaking in the near-source region (Luzi et
In this study, we select data from strong-motion stations within an epicentral distance of 200 km.
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The distributions of the selected data with respect to distance, magnitude and distance, magnitude and number of stations per EC8 soil classes (Eurocode 8, 2004) are summarized in Figure 3. The site conditions at each strong-motion station are expressed through the EC8 soil categories, which is based either on the average shear-wave velocity of the upper-most 30 m (VS,30 ) or on the available geological information. Most of the selected stations are classified as site class B/stiff soil.
11
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Figure 2: Epicentres (stars) of the nine Mw ≥ 5.0 earthquakes of the sequence. Mw ≥ 2.5 aftershocks for one year after the Amatrice mainshock are also mapped with blue dots. [source: http://cnt.rm.ingv.it/]
Event
Event Time
Latitude [°]
Longitude [°]
Depth [km]
Amatrice
Mw
# Records
24/08/2016 01:36
42.70
13.23
8.1
6.0
158
Amatrice Aftershock
24/08/2016 02:33
42.79
13.15
8.0
5.3
138
Visso I
26/10/2016 17:10
42.88
13.13
8.7
5.4
158
Visso II
26/10/2016 19:18
42.91
13.13
7.5
5.9
166
Norcia
30/10/2016 06:40
42.83
13.11
9.2
6.5
159
Montereale I
18/01/2017 09:25
42.55
13.26
9.2
5.1
127
Montereale II
18/01/2017 10:14
42.53
13.28
9.1
5.5
141
Pizzoli I
18/01/2017 10:25
42.49
13.31
8.9
5.4
129
Pizzoli II
18/01/2017 10:33
42.48
13.28
10.0
5.0
124
Table 2: Main characteristics of the largest events of the Central Italy sequence [source: Lanzano et al. (2018)].
12
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Figure 3: (a) Records-distance distribution; (b) Magnitude-distance distribution; (c) Events-magnitude distribution; (d) Distribution of stations in terms of EC8 site classification. Distances are in terms of Joyner and Boore distance (Rjb, i.e. the distance to the surface projection of the rupture).
3.2. Simulated ground-motions fields To simulate spatially-correlated ground-motion fields, we employ the approach described in Strasser and Bommer (2009), which accounts for both the between- and within-event variabilities. The former is specified through the between-event standard deviation in the IMs computation, whereas the latter is included through the computation of a random field based on a multivariate normal distribution. The procedure includes the following steps:
13
Journal Pre-proof ). We employ the GMPE by
1. Generation of deterministic fields using GMPEs (
Lanzano et al. (2019) for shallow crustal earthquake in Italy, considering homogeneous rock site conditions (Figure 4a). 2. Generation of ground motion random fields (Figure 4c). (
The spatially correlated random field
) is computed through a multivariate
normal distribution characterized by an exponential correlation model with correlation and standard deviation
(5,
(0.1, 0.32 and 0.5) to allow a deeper insight into the impact of
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10 and 30 km) and
(see section 2). We choose different values of
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length
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these parameters on the analysis.
3. Generation of ground-motion stochastic fields (Figure 4b).
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This is obtained by combining steps 1 and 2:
The ground-motion fields are generated on a 200 km
(
)
( )
200 km grid with a 2 km resolution. Finally,
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we randomly locate strong-motion recording stations throughout the region and use the simulated pair to obtain stable results.
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IMs at these stations. We repeat the process 1000 times for each
14
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Figure 4: Example of deterministic (a), stochastic (b) and random (c) ground-motion fields. obtained through the above-described approach. PGAs are expressed in cm/s 2 . The triangles represent the stations used in the analysis.
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4. Modelling of spatial correlation
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4.1. Estimation of the within-event spatial correlation
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It is common practice to adopt an existing GMPE or an ad hoc study-specific GMPE to compute the within-event residuals at each site in order to assess the within-event spatial correlation
( ). This
can be estimated with two different approaches, namely: (1) computing directly the covariance and the correlation coefficient (e.g. Wang and Takada, 2005; Sokolov et al., 2010, 2012), or (2) calculating the sample semivariogram, which measures the average dissimilarity between spatially distributed data (e.g. Jayaram and Baker, 2009; Esposito and Iervolino, 2011, 2012; Wagener et al., 2016; Heresi and Miranda, 2019; Sgobba et al., 2019). In the first method, the spatial correlation is estimated as:
( )
(
)
( )
15
Journal Pre-proof where COV denotes the covariance function, whereas
and
are the within-event variabilities
for the ith and kth sites during the jth event with zero mean and standard deviation
.
The second method computes the experimental semivariogram to represent the spatial dependency of IMs values with varying separation distance, which is defined as: ̂( )
] ( )
[
in which Var indicates the variance. It is common practice to adopt two different estimators to
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compute the sample semivariogram: 1) Method of moments (Matheron, 1962)
∑{
pr
̂( )
}
( )
( )
e-
( )
Pr
where ̂ ( ) represents the empirical semivariogram and N(h) is the number of pairs separated by h.
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2) Estimator proposed by Cressie (1985)
∑ [ | ( )|
{
| ]
(
| ( )|
)
}
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̂( )
( )|
This is found to be a more robust estimator, being less sensitive to outliers (Esposito and Iervolino, 2012; Du and Wang, 2013; Oliver and Webster, 2014). Both the covariance and the semivariogram are calculated for each pair of stations ( inter-site spacing falls in a distance bin defined as
|
|
) whose
. Esposito and
Iervolino (2012) and Du and Wang (2013) suggest setting the bin size in such a way that there are at least 30 pairs in each bin. Other authors (e.g. Wagener et al., 2016) advise having at least 100 pairs per bin to have more reliable and representative estimations. Furthermore, the definition of primary importance.
is of
can be estimated either from the sample semivariogram at large separation
distances, where the within-event residuals are assumed to be uncorrelated, or as the standard 16
Journal Pre-proof deviation of the within-event residuals for a given event (Goda and Atkinson, 2010). Alternatively, Esposito and Iervolino (2012) employ the standard deviation related to the GMPE as
. However,
this approach is strongly discouraged by other studies, since using a constant value of
for
different events might lead to a biased within-event correlation (Heresi and Miranda, 2019, FoulserPiggott and Goda, 2015). Parametric functions are used to fit the experimental values computed either through the sample to be retrieved
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semivariogram or covariance approaches. This allows for the spatial variation of
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for any separation distance h. Examples of basic second-order stationary and isotropic models are:
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(1) Matérn; (2) Exponential; and (3) Gaussian (Webster and Oliver, 2007). The exponential model
( )
(
)] (
)
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[
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(Figure 5), which usually provides the best performance, takes the form:
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where h is the separation distance, a and b are the sill and the range of the semivariogram and c is a given positive constant set to 3. The sill equals the variance of the data, whereas the range
( ) equals 0.95 times the sill. It is worth mentioning that in some studies (e.g.
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distance at which
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represents the distance beyond which the correlation between sites is negligible. The range is the
Wang and Takada, 2005; Huang and Galasso, 2019) c is set equal to 1. Consequently, the range outlines
the
distance
at
which
the
correlation equals
(
)
(
)
.
The
implementation of either one or the other value leads to a different meaning of the range, without however affecting the spatial correlation structure of the IM of interest. Moreover, under the hypothesis of second-order stationarity, the semivariogram and the covariance function are equivalent, so that the following relation holds (Oliver and Webster, 2014): ( ) being
( )
(
)
(
)
( )
(
)
. 17
Journal Pre-proof Consequently, combining Eq. (11) and Eq. (12), we have that: ( )
( )
) (
(
)
which is equivalent to Eq. (3). Furthermore, the hypothesis of second-order stationarity may sometimes not hold. The expected value of the random variable
may not be constant across all sites, but indeed varying
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depending on the location. In such cases, the semivariogram ̂ ( ) increases with separation
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distance, without reaching a stable sill (Diggle and Ribeiro, 2007). These long-range spatial trends
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should be removed so that small-range correlation structures can be detected. It is common practice to model spatial trends through trend surface models, namely the mean function is described by
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either first- or second-order polynomial functions of the geographic coordinates (Diggle and
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Ribeiro, 2007; Oliver and Webster, 2014). Alternatively, the trend and the semivariogram of the residuals can be estimated all at once through the residual maximum likelihood approach, as
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suggested by Oliver and Webster (2014).
Figure 5: Exponential model. The black solid line is the theoretical model, whereas black squares represent the experimental semivariogram. The sill and range parameters are also highlighted.
Different approaches have been used in previous studies to fit the experimental data, such as the weighted least-squares and manual-fitting techniques. Jayaram and Baker (2009), among others, suggest inferring the model parameters manually so that the experimental data are better fitted at 18
Journal Pre-proof shorter separation distances. This technique should, however, be discouraged as it involves a certain degree of subjectivity that can lead to prediction errors. Regarding the least-squares approach, weights can depend on either the separation distances (e.g. increasing the weights of data at shorter distances) or the number of pairs in each bin. 4.2. Modelling caveats The previously described approach suffers from some shortcomings. GMPEs (eq. 1) are usually
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developed through regression analysis using either the two-stage algorithm proposed by Joyner and Boore (1993) or the one-stage mixed-effects approach by Abrahamson and Youngs (1992),
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considering independent within-event residuals. The similarity of the earthquake source, path and
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local-site effects leads to spatially correlated within-event residuals. This issue was firstly
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investigated by Hong et al. (2009), who demonstrated that the inclusion of spatial correlation in GMPE development does not affect the estimated ground motion model coefficients but it does
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affect the variability of the between- and within-event residuals. In particular, the between-event
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variance decreases, whereas the within-event component increases, with consequences for the assessment of seismic risk of spatially-distributed systems. Similarly, Jayaram and Baker (2010)
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adopted a different approach and drew analogous conclusions. While spatial correlation model parameters can be inferred from statistical analysis of residuals independently of GMPE regressions, caution must be applied in the estimation of Φ and τ. Ming et al. (2019) reviewed the studies by Hong et al. (2009) and Jayaram and Baker (2010), and pinpointed their main limitations. They proposed a new algorithm (the scoring estimation approach) that, while achieving the same results in terms of Φ and τ, provides more statistically robust ground-motion models along with spatial correlation parameters to improve seismic hazard and risk assessments. In addition, seismic risk analyses usually employ an average estimate of the correlation structure, derived considering heterogeneous databases, without accounting for its event-to-event variability. Goda (2011) investigated the event-to-event variability of within-event spatial correlation, studying 19
Journal Pre-proof 41 different earthquakes individually. He found that the model by Goda and Atkinson (2010) reasonably fits the overall median tendency. However,
units should be added to the same
spatial correlation model to take into account the event-to-event uncertainty. Likewise, Heresi and Miranda (2019) quantified the event-to-event variability, comparing the within-event residuals correlation of 39 well-recorded earthquakes. They provided general equations to calculate the median and dispersion of the correlation length (range), so that the uncertainty can be easily
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accounted for in regional seismic risk computations.
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In Figure 6, we compare the outcomes obtained analysing the data from the 2016-2017 Central
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Italy sequence with the models proposed by Goda (2011) and Heresi and Miranda (2019) along with their event-to-event uncertainty. We follow the approach described in Heresi and Miranda
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(2019) to compute the central tendency and the standard deviation, based on the number of stations
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that recorded each event. The Central Italy database features a smaller event-to-event variability because all the earthquakes nucleated within the same region. Conversely, the two other models are
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calibrated on worldwide datasets, leading to a larger variability in terms of correlation length.
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According to our analysis, a region-specific variability should be considered when performing
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regional seismic hazard and risk assessment to obtain more accurate results.
20
Journal Pre-proof Figure 6: Correlation models proposed by Goda (2011) and Heresi and Miranda (2019) [HM19] and obtained considering data from the Central Italy sequence for PGA (a) and SA(3 s) (b). Solid lines represent the median values, whereas shadow areas indicate the event-to-event uncertainty. Black dashed line helps indicate the distances at which the correlation equals 0.05.
5. Major factors influencing spatial correlation In this section we present a detailed literature review and the results from our analyses, with the aim of understanding the main factors that affect the spatial correlation of ground-motion IMs.
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5.1. Dependence on the estimation approach
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In section 4.1 we described two different approaches to estimate the within-event spatial
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correlation, namely: (1) the covariance and correlation coefficient and (2) the semivariogram. The
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implementation of either one or the other technique should provide similar results as the semivariogram and the covariance are equivalent for second-order stationary random fields. Goda
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and Hong (2008) compared the results obtained for the Mw 7.6 Chi Chi earthquake using both the
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approaches and found that the computation of the covariance provides slightly different estimates. Similarly, Goda and Atkinson (2009), while characterizing the spatial correlation of Japanese data,
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drew the same conclusions. The correlation decays faster when the correlation coefficient is directly
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computed, and some inconsistent trends may occur, especially if the number of available data is inadequate. Nevertheless, they provided a general correlation model by averaging the results obtained using both approaches, as subsequently suggested by Sokolov et al. (2012, 2013). In order to address this issue, we carry out a thorough geostatistical analysis of the within-event correlation structure using simulated spatially-correlated ground-motion fields. We compute the range implementing both the techniques and both the sample semivariogram estimators by varying the number of sites. As found by Goda and Hong (2008) and Goda and Atkinson (2009), the direct estimation of the correlation coefficient not only features slightly different results, but also a larger dispersion compared to the semivariogram approach in our simulations (Figure 7). Furthermore, the graph well illustrates how the availability of stations plays a crucial role in obtaining more robust 21
Journal Pre-proof outcomes: even though the mean of h0 assumes to some extent a constant value, the uncertainty
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halves as the number of stations increases.
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Figure 7: Estimated range h0 normalized by the true value of the range h* 0 as a function of the number of sites (stations) using: (a) the Cressie and Hawkins (robust) estimator; the Matheron (classic) estimator; and (c) the covariance approach. Grey squares represent the mean value, whereas the solid vertical lines indicate the variability of the estimates. The red dashed line signifies a ratio of 1.
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Most of the proposed models use the classic estimator of Mathéron (1962) to compute the sample
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semivariogram. The estimates obtained are variances and as such they are sensitive to outliers, which might lead to less reliable semivariograms. A statistically more robust estimator was
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proposed by Cressie (1985) to down-weight the effects of atypical observations (Oliver and
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Webster, 2014). Esposito and Iervolino (2011, 2012) implemented both the estimators, concluding that there are negligible differences. Du and Wang (2013) suggested using the robust approach directly to obtain consistent estimations. Clearly, the two different estimators provide almost the same correlation distance in terms of average value, as observed in Figure 7 and according to Esposito and Iervolino (2011, 2012). However, a more in-depth analysis suggests that: (1) the classic estimator is likely to converge faster; (2) the two different approaches do not provide always the same range, as shown in Figure 8. In particular, the smaller the number of considered stations, the more significant are the differences. Although our simulations do not show which is the best semivariogram estimator, Oliver and Webster (2014) demonstrated that if the data features outliers, the classic estimator diverges from the input function, in contrast to the robust estimator. 22
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5.2. Dependence on the fitting method
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Figure 8: Comparison between the ranges obtained through both the classic and robust estimators, considering different numbers of stations.
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A number of methods have been proposed to fit experimental values by means of parametric
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models. The trial-and-error (manual fitting) and least-squares regression, among others, are the most common techniques. Jayaram and Baker (2009) recommend manually fitting the experimental semivariogram so that shorter separation distances, which are more important for engineering purposes, are weighted higher. Despite its high degree of subjectivity, this approach was chosen also by Du and Wang (2013) for its versatility in fitting the data. Esposito and Iervolino (2011) and Infantino et al. (2018) visually fitted experimental semivariograms, assuming the least-squares regression as a basis. Conversely, other studies, such as Esposito and Iervolino (2012), Sokolov et al. (2012), Wagener et al. (2016), Heresi and Miranda (2019) and Sgobba et al. (2019), adopt the weighted least-squares regression approach, using different weights. Some of the authors prioritise either the short separation distances or the number of pairs in each bin; others apply the same weight to all the experimental values, so that the model is fit equally over the full range of data. In 23
Journal Pre-proof our analysis, we opt for the weighted least squares regression, in which weights are computed based both on the number of pairs and on the separation distance, so that the impact of longer distances is minimized as they are associated with low correlations (Jayaram and Baker, 2009). However, we carry out a further analysis in which all the data are equally weighted to understand the influence of the fitting method on the correlation structure. Figure 9 illustrates how the different weightings lead to dissimilar results. A similar comparison can be found in Jayaram and Baker (2009), where the authors criticised the study by Wang and Takada (2005). Stafford et al. (2018) achieved similar
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outcomes, arguing that there is variability in the ranges due to the adopted technique. Therefore, according to Jayaram and Baker (2009), among others, we suggest prioritising models that fit the
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experimental data well at short separation distances, which have a significant impact on seismic risk
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estimates.
Figure 9: Correlation models obtained through the robust (a) and classic (b) estimators. Blue curves indicate the results in which the weights used to fit the experimental data are computed based on the number of pairs and separation distance; red curves represent the results in which equal weights are applied to all the data. Shadow area represent the standard deviation of the results computed on 1000 simulations. The standard deviation of the model with weights (8.7 and 7.12 km for the robust and classic estimators respectively) is smaller than the standard deviation of the model without weights (9.02 and 7.73 km).
5.3. Dependence on magnitude The relationship between magnitude and correlation length is one of the most debated topics in studies of spatial correlation. Some studies (e.g. Sokolov et al., 2012, 2013; Foulser-Piggott and 24
Journal Pre-proof Goda, 2015) argue that the range tends to increase with increasing magnitude because moderate-tolarge earthquakes feature lower frequency content and hence an additional non-random component. Conversely, other authors (e.g. Jayaram and Baker, 2009) did not find any correlation between these two parameters. Heresi and Miranda (2019) performed a statistical analysis and found that only a small ratio of the variability in terms of correlation length can be explained by considering the magnitude, in particular for SA at longer periods. Garakaninezhad and Bastami (2017) showed that there is a positive correlation between magnitude and anisotropy ratio (ratio between the ranges of
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the direction with the largest and smallest spatial correlations, respectively) of residuals for the nine earthquakes analysed. This is valid only for PGA, however, and it does not apply to spectral
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accelerations.
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In Figure 10 we compare the ranges obtained for each
earthquake belonging to the
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Central Italy seismic sequence as a function of magnitude. The results do not suggest any clear relationship between range and magnitude, at least for this
interval, in agreement with the
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findings of Jayaram and Baker (2009). It is worth noting that both Sokolov et al. (2012, 2013) and
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Foulser-Piggott and Goda (2015) analysed a wider range of events in terms of magnitude, grouping . We believe that our analysed database
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as moderate-to-large earthquakes all events with
represents too narrow a magnitude interval to draw sound conclusions on the relationship between magnitude and range. Besides, it is biased towards small-magnitude earthquakes, which could influence the result. Other factors should be considered to explain the variability in terms of correlation length, especially when the same seismic region is considered. Stafford et al. (2018) demonstrated that the rupture process of events of equal magnitude has a significant contribution on the variability in the range. Likewise, while studying correlation spatial patterns using physicsbased ground-motion simulations, Chen and Baker (2019) found a dependence of the correlation on source effects and on the relative position of a site with respect to the fault asperities.
25
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Figure 10: Range as a function of magnitude: (a) PGA; (b) SA(4s). Ranges are obtained by means of the robust semivariogram. We also apply a detrending processing using second-order surface models to remove long-range spatial trends.
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5.4. Dependence on period
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Previous research (e.g. Goda and Hong, 2008; Jayaram and Baker, 2009; Esposito and Iervolino, 2012; Wagener et al., 2016; Infantino et al., 2018; Sgobba et al., 2019; Chen and Baker, 2019) has
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demonstrated that the spatial correlation structure is affected by the response-spectral period
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considered. Range and period are found to be directly proportional. This is consistent with studies
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on ground-motion coherency, a measure of similarity between waveforms and phases of two ground-motion time histories recorded at two different sites. Hough and Field (1996) demonstrated that ground motions at frequencies up to 2-3 Hz and distances up to 3-4 km are characterized by a high level of waveform coherence, which by contrast drops for shorter period ground motions. Zerva
and
Zervas (2002),
while investigating spatial coherency,
proved
that small-scale
heterogeneities in the travelling path strongly affect the short-period waves (short wavelengths), which therefore tend to be less coherent, in contrast to long-period waves. Figure 11 provides an overview of the correlation lengths as a function of period of the above-mentioned studies. All the range values in Figure 11 are computed as the distance at which the correlation equals 0.05 in order to compare the results. Esposito and Iervolino (2012) and Wagener et al. (2016) showed that at 26
Journal Pre-proof short periods (up to 0.5 s) it is not possible to clearly delineate a trend between range and period. Goda and Atkinson (2010) found that the correlation is clearly affected by the vibration period especially at short separation distances (h < 10 km), in contrast to greater distances (h > 50 km), where the models tend to converge towards similar results. Consequently, they proposed an average constant model (Figure 11), calibrated on the results obtained at nine different periods. To further test the hypothesis of a dependence of the correlation on period, here we present a model for the events.
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Central Italy sequence computed by pooling all the data from the nine
Figure 11: Range as a function of response-spectral period, T. The main studies are reported along with a model for the Central Italy seismic sequence, denoted as “This study”. This model is calibrated by pooling all the data from the nine Mw ≥ 5.0 events. The model of Jayaram and Baker (2009) refers to their model for heterogeneous soil condition, whereas the model of Du and Wang (2013) is computed considering a Vs30 correlation of 4.5 km.
As we summarise in Figure 12, we observe the increasing trend with period for all events of the sequence taken individually, as well.
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Figure 12: Range as a function of response-spectral period, T, computed using the robust estimator for the nine events of the sequence. In black we reported the weighted (geometric) average model, in which the weights are given based on the number of stations that recorded each event.
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5.5. Dependence on local site effects and geological structure Several studies (e.g. Jayaram and Baker, 2009; Sokolov et al., 2010, 2012; Du and Wang, 2013;
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Infantino et al., 2018; Chen and Baker, 2019) indicated that the level of correlation is strongly
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influenced by regional geologic and site conditions, especially when short-period IMs are of
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interest. Conversely, Heresi and Miranda (2019) demonstrated that the clustering of Vs30 values does not explain the high variability in the correlation length. To address this issue, we develop an ad hoc GMPE for the Central Italy sequence without accounting for different site conditions and then we introduce a site-specific correction factor to remove any dependency on local-site effects, following Sokolov et al. (2010, 2012, 2013). The within-event spatial correlation is understood as a non-random component in the residuals, which arises from neglecting a number of factors in the GMPE, such as site, path and azimuth as well as hanging-wall and footwall effects (Sokolov et al., 2012, 2013). Due to the shortage of data, we could not derive a correlation model for each site class, similarly to Sokolov et al. (2012, 2013). The following functional form is assumed: ̅
(
)
√
(
) 28
Journal Pre-proof where ̅ is the PGA or SA(T) for T equal to 0.2, 0.5, 1, 2, 3 and 4 s and
is the Joyner-Boore
distance (or the epicentral distance for those events where the fault geometry is not defined and the point-source approximation holds).
and
are the model coefficients inferred through
the maximum-likelihood regression method by Joyner and Boore (1993). It is noted that our main goal is to estimate the residuals for correlation purposes, and not to develop a new GMPE; therefore, we keep the functional form as simple as possible. The between-event and within-event residual components are evaluated using the mixed-effects approach. In the same way, we compute , which represents the site-specific deviations from the
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the site-specific correction term
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average model calibrated considering all sites in the dataset, as explained in Kotha et al. (2018). We evaluate the sample semivariogram through equation (eq. 10) and we fit the values using the
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weighted least-squares approach (section 5.2) considering an exponential model (eq. 11). We follow
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the approach of Esposito and Iervolino (2011, 2012) to pool data from different events. We repeat these steps including the site-specific correction term, so that the corrected IM is: ̅
(
)
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̅
Figure 13 provides an overview of the within-event correlation models obtained considering or not
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the site-specific correction term. Similarly to Sokolov et al. (2010, 2012, 2013), the range decreases if a correction factor is included in the analysis, suggesting that neglecting site conditions might add an artificial correlation due to systematic biases in the residuals (Stafford et al., 2018). Besides, the lower level of correlation found at longer periods (grey curve) requires further analysis, since the local-site effects influence is expected to decrease with increasing period, as demonstrated by Jayaram and Baker (2009) and Infantino et al. (2018), among others.
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Figure 13: (a) Range as a function of the response-spectral period, T, for within-event residuals (dWes) with and without the site correction factor; (b) Correlation function in terms of PGA for within-event residuals with and without the site correction factor. The black dashed line indicates a correlation of 0.05.
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Furthermore, the level of correlation of Vs30 values can be used as a proxy to represent either homogeneous or heterogeneous local-soil conditions in terms of local-site effects, since a smaller
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correlation indicates a more varied geological setting. Jayaram and Baker (2009) identified a
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positive relationship between clustering of Vs30 values and correlation of spectral accelerations, especially at shorter periods. They proposed a model to predict the range as a function of both the
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period and the Vs30 range. Similarly, Du and Wang (2013) drew analogous conclusions, illustrating
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that the influence of local-site effects on the correlation of spectral accelerations drops with increasing period. Sokolov et al. (2012) provided a relationship between the PGA range and the Vs30 correlation, after finding a dependency of these parameters for different regions in Taiwan. Garakaninezhad and Bastami (2017) found that the anisotropy ratio of residuals tends to increase as the anisotropy ratio of Vs30 increases. However, this positive correlation is significant only for PGA, similarly to the relationship with magnitude. To further emphasis this aspect, Figure 14 compares the above-mentioned studies along with a model calibrated on the
events of the Central
Italy sequence. We develop the latter using the code by Ming et al. (2019), which was also used in Huang and Galasso (2019) to study the correlation observed in Italian data. Two main observations are worthy of remark. Firstly, the effects of local-soil conditions on spatial correlation models are 30
Journal Pre-proof much greater at shorter periods, compared to longer periods where the different models practically overlap. Secondly, the comparison between the Huang and Galasso (2019) and Central Italy models suggests that the correlation strongly depends on the geological characteristics of the considered area, so that a single universal correlation model based on large datasets is not suitable to represent small regions. Indeed, the model of Huang and Galasso (2019) is obtained by including events that occurred in all of the Italian mainland, thus leading to an average spatial correlation model calibrated on diverse geological contexts, with variable spatial dependency of IMs. The same was
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also previously demonstrated by Sokolov et al. (2010, 2012, 2013) for Taiwan. Besides, this behaviour is particularly evident at shorter periods, in agreement with different studies, such as
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Jayaram and Baker (2009) and Du and Wang (2013), in which these authors demonstrated the
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impact of local-site effects as a function of period. Figure 11 illustrates this aspect: the Central Italy
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and the Huang and Galasso (2019) models nearly coincide for T>1 s.
Figure 14: Correlation function in terms of PGA (a) and SA at T = 2 s (b). The model referred as “This study” is computed by means of the code developed by Ming et al. (2019) using data from the nine central Italy earthquakes. The red shadow area represents the 95% confidence intervals of the central Italy model. The black dashed line indicates a correlation of 0.05.
5.6. Dependence on GMPEs To develop a correlation model either an existing GMPE or an ad hoc relation is used to assess the within-event residuals. Authors, such as Wang and Takada (2005), Jayaram and Baker (2009), 31
Journal Pre-proof Esposito and Iervolino (2011, 2012) and Wagener et al. (2016), employed and existing ground motion model in their analyses. Conversely, other authors such as Goda and Hong (2008), Goda and Atkinson (2009, 2010), Sokolov et al. (2010) and Infantino et al. (2018) developed a GMPE calibrated on their specific dataset. Du and Wang (2013) asserted that the chosen GMPE does not affect the correlation results. Analogously, Jayaram and Baker (2009) and Goda (2011) demonstrated that similar outcomes are achieved if different GMPEs are used. In contrast, Sokolov et al. (2010) maintained that the decomposition of the total aleatory variability into between- and
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within-event components is influenced by the particular GMPE and hence the spatial correlation is affected in turn, as it is calibrated on the residuals. Infantino et al. (2018) built a ground-motion
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model based on their databases to avoid any dependency on the GMPE. Likewise, we opt for the ad
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hoc GMPE approach and we develop a study-specific ground-motion model, as described in section event of the Central Italy sequence to
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5.5. We also calibrate ad hoc models for each
and
√
(
)
are the model coefficients inferred through a one-stage ordinary regression,
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where
√
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̅
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obtain a specific correlation model for each earthquake. We assume the following functional form:
which is justified as we are only using data from a single event each time. We show some of the results in Figure 10 and Figure 12.
To investigate the dependence of spatial correlation on the chosen ground-motion model, we repeat all the analyses using the GMPE provided by Bindi et al. (2011), which is also calibrated on Italian data. This model was found by Michelini et al. (2019) to be the most suitable to predict ground motions in shallow active crustal regions in Italy. Figure 15 presents a comparison between the correlation models obtained implementing both the ad hoc and Bindi et al. (2011) GMPEs. We plot the results illustrated in section 5.5, in which we consider both uncorrected and corrected withinevent residuals. Interestingly, the Bindi et al. (2011) model provides nearly the same range as the 32
Journal Pre-proof model obtained including a site correction term for short-period IMs. At longer periods, the Bindi et al. (2011) model approaches the range value inferred without incorporating any site correction factor. We interpret these outcomes by also considering the results that we present in section 5.5. The Bindi et al. (2011) GMPE takes into account the local-site effects through the definition of coefficients based on the EC8 soil categories. Local-soil conditions most influence the spatial correlation of short-period IMs and thus, it is not just chance that the correlation model inferred through the Bindi et al. (2011) GMPE tends to the range obtained implementing a site-specific
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correction term. Conversely, the influence of site conditions at longer periods is weaker, and the
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Bindi et al. (2011) and the uncorrected correlation models nearly coincide.
Figure 15: Within-event (dWes) correlation models for uncorrected and corrected residuals and computed considering the GMPE by Bindi et al. (2011): (a) PGA; (b) spectral acceleration for T equals 2 s.
Overall, we believe that any GMPE can be used, provided that the selected ground-motion model fits the data well, so that the residuals do not exhibit biases. Systematic deviations from the predicted median might be mapped as an additional artificial correlation, which inevitably would affect the seismic hazard and risk assessments of spatial distributed systems. This behaviour is shown in Figure 16, in which we compare the semivariograms obtained considering both the GMPE by Bindi et al. (2011) and Boore and Atkinson (2008). Clearly, the Boore and Atkinson (2008) semivariogram diverges from the Bindi et al. (2011) with increasing separation distance. 33
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IMs.
6. Conclusions
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Figure 16: Sample semivariogram obtained using the GMPEs by Boore and Atkinson (2008) and Bindi et al. (2011).
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In this article, we aimed to provide insights into the spatial correlations of earthquake ground-
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motion intensity measures. A number of studies, such as Park et al. (2007) Goda and Atkinson (2009) Esposito and Iervolino (2011) and Verros et al. (2017), highlighted the importance of considering such spatial correlations in seismic hazard and risk analysis, especially when the seismic risk of spatially distributed systems has to be evaluated. Nevertheless, the correlation models proposed over the past two decades feature significant discrepancies, which may lead to underestimation or overestimation of the assessed seismic risk. Therefore, in this article, we critically summarised the main findings of previous studies and we attempt to address the primary questions about ground-motion spatial correlation. We showed the two main approaches to estimate the spatial correlation of ground-motion intensity measures. In principle, the implementation of either one or the other technique is expected to 34
Journal Pre-proof provide similar results, as the semivariogram and the covariance are equivalent for second-order stationary random fields. Nevertheless, in agreement with Goda and Hong (2008) and Goda and Atkinson (2009), we find that the results slightly diverge. Concerning the computation of the semivariogram, the robust estimator (Cressie) is understood to be less sensitive to atypical observations, as demonstrated by Oliver and Webster (2014). Therefore, we preferred using this estimator in contrast to the classic one throughout the analyses, although the results from our simulations did not find any significant difference between the two estimators. To fit experimental
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data, we advise prioritising those techniques that weigh the shorter separation distances more highly, since these distances have a strong impact on seismic hazard and risk assessments of
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spatially-distributed systems. At the same time, we discourage adopting a manual fitting due to the
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high level of subjectivity involved.
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Similarly to Jayaram and Baker (2009), we do not find any relationship between magnitude and correlation distance. We are aware that the analysed dataset is limited in terms of magnitude range
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(Mw 4.0 to 6.5), so that firm conclusions cannot be drawn on this aspect. However, we believe that
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magnitude itself cannot explain the large variability of correlation distance values, especially when
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the same region is considered. Thus, other source effects, such as directivity, azimuth and hanging wall and footwall effects, should be accounted for, as outlined in Stafford et al. (2018) and Chen and Baker (2019).
We found a positive correlation between the range and response-spectral period, as expected from the literature. Small-scale heterogeneities in the travel path tend to affect less the long-period waves, which turn out to be more correlated, compared to high- frequency waves. We analysed the dependency of the spatial correlation on local-soil conditions, illustrating that the influence of local-site effects and regional geology is period-dependent, as demonstrated by several authors, such as Jayaram and Baker (2009), Du and Wang (2013) and Infantino et al. (2018). The comparison between our analysis of data from Central Italy and the work proposed by Huang and 35
Journal Pre-proof Galasso (2019) is significant. Firstly, it confirms the hypothesis that the dependency of spatial correlation on site conditions in terms of local-site effects decreases as the period increases. Secondly, it suggests that a single rate of decay of the correlation as a function of the inter-site separation distance is not suitable for seismic hazard and risk assessment, as the range appears to be regionally-dependent, even though all the data came from the same country (Italy in this case). We believe that region-specific spatial correlation models should be derived.
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Finally, our results suggest that any suitable ground-motion model can be applied in correlation
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studies, provided that the residuals do not exhibit significant trends or biases, which might result in
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an apparent larger correlation. Therefore, a single correlation model could be used in seismic hazard analysis even if many different GMPEs are employed to estimate ground-motion parameters.
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However, as suggested by Sokolov et al. (2012), implementing a logic tree for correlation models as
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already incorporated in probabilistic seismic hazard assessments, should be encouraged to account
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for the high uncertainty in spatial correlation models.
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We note that generally the models are poorly constrained at short separation distances (less than 2 km), due to a shortage of observations (Goda and Atkinson, 2010; Wagener et al., 2016). Results of
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ground motion simulations could provide better constraints to further advance insights into the spatial correlation of ground motions.
Data and resources
The full dataset of strong-motion waveforms of the nine
earthquakes of the 2016-2017
Central Italy sequences is available at the Engineering Strong Motion database (ESM, http://esm.mi.ingv.it, last accessed September 2019) and the Italian ACcelerometric Archive (ITACA, http://itaca.mi.ingv.it, last accessed September 2019). The full dataset of recordings of the events of the 2016-2017 Central Italy sequences is available at http://cnt.rm.ingv.it/ (last accessed September 2019).
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Acknowledgements
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We thank the research group of Dr Francesca Pacor at INGV (Istituto di Geofisica e Vulcanologia) for providing the dataset related to the events that occurred during the Central Italy earthquake sequence. We also thank Dr Sreeram Reddy Kotha for his helpful suggestions about implementing mixed-effects regressions in R. We thank Dr Deyu Ming for help with the MATLAB program to implement the approach of Ming et al. (2019). We wish to thank Professor Jack Baker’s research group at Stanford University for providing valuable feedback on our analyses. We are grateful to Impact Forecasting for fruitful discussions on hazard footprints. We thank Graeme Weatherill and an anonymous reviewer for their constructive advice on improving the manuscript. Finally, we thank the University of Strathclyde for funding the PhD during which the work was undertaken.
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Akkar, S., and Bommer, J. J. (2010). Empirical equations for the prediction of PGA, PGV, and spectral accelerations in Europe, the Mediterranean region, and the Middle East. Seismological Research Letters, 81(2), 195-206.
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Du, W. and Wang, G. (2013) ‘Intra-event spatial correlations for cumulative absolute velocity, arias intensity, and spectral accelerations based on regional site conditions’, Bulletin of the Seismological Society of America, 103(2 A), pp. 1117–1129. doi: 10.1785/0120120185.
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